Cortical Granule Release Research Articles

The cortical reaction and development of activation competence in mammalian oocytes.

Blocks to polyspermic fertilization are necessary to prevent the incorporation of two sperm nuclei into a zygote's genome, which would result in abnormal development. Many mammalian eggs utilize both an extracellular zona pellucida block to polyspermy and a plasma membrane block. Although little is known about the plasma membrane block in mammals, fertilization results in zona glycoprotein modifications caused by enzymes released by the egg and its cortical granules (CG). This article reviews other recent investigations demonstrating that the oocyte's ability to cause CG release and the block to polyspermy develops near the time of ovulation. The development of normal "activation competence' is likely to involve preovulatory changes in the oocyte's ability to signal the release of intracellular calcium as well as to respond to this calcium increase, resulting in CG exocytosis. Because normal activation competence appears to have a brief temporal window after oocyte meiotic maturation is resumed and since the oocytes are collected at various stages in assisted reproductive procedures, these studies are relevant to optimizing clinical success.

A zona biochemical change and spontaneous cortical granule loss in eggs that fail to fertilize in in vitro fertilization

To determine the extent of biochemical changes in the zona pellucida (ZP) and cortical granule release in eggs failing to fertilize in IVF. After insemination, unactivated eggs without two pronuclei (PN) were studied by high resolution microscopy and fluorescent probes to determine cortical granule density and meiotic stage. After ZP isolation, proteins from individual ZPs were biotinylated, electrophoresed, and visualized by western blots with avidin-chemiluminescence. Controls included mouse unfertilized and fertilized eggs and human germinal vesicle stage oocytes and ≥ 3PN eggs. University medical center and hospital tertiary care IVF-ET program. Many of the unfertilized eggs were in metaphase and had relatively low cortical granule densities indicative of cortical granule loss. Approximately one half of the ZPs showed evidence of biochemical hardening with a modification of a 90 to 100 × 10 3 molecular (weight) ratio (M r ) ZP protein. The 3PN eggs had few cortical granules and their ZPs had a pronounced 90 to 100 × 10 3 M r modification that was not detected in germinal vesicle stage ZP controls. The observed changes in ZP biochemistry and cortical granule quantitation demonstrate that failed fertilization is frequently associated with spontaneous cytoplasmic, but not nuclear, activation. In affected eggs, these changes could prevent fertilization in routine IVF and in cases of reinsemination. The relationship of changes in the ZP and cortical granules to infertility and in vitro culture requires further investigation. The 90 to 100 × 10 3 M r ZP protein modification can be detected biochemically with 1 10 of a human ZP.

Parthenogenic activation of pig oocytes by protein kinase inhibition.

Previous studies have shown that protein kinase stimulators can induce the release of the metaphase II arrest in mouse ova. The present report is about the role of protein kinase in parthenogenic activation of pig oocytes, which was studied using a broad-spectrum protein kinase inhibitor. Metaphase II oocytes were obtained via in vitro maturation. Two sources of H7 [1-(5-isoquinolinesulfonyl)-2-methylpiperazine, HCl] were tested--Sigma (H7s) and Calbiochem (H7c). Both were found to be equally effective in promoting release of the metaphase II block. Activation, release of the metaphase II arrest, and progression to the first interphase could be induced at the highest percentage with an exposure to 2.0 mM H7s for 80 min (68.1%). In another experiment, H7c resulted in 69.5% activation, while iso-H7 [1-(5-isoquinolinesulfonyl)-3-methylpiperazine, HCl] at a similar concentration and exposure duration resulted in 25.7% activation. H7s and H7c were more effective than iso-H7 in inducing the appearance of a 22-kDa protein that is associated with normal fertilization in the pig. In contrast, although pronuclei could form and the protein profiles were indicative of activation, cortical granule exocytosis did not occur, and oocytes failed to develop to the blastocyst stage after H7 treatment. In contrast to the H7-treated oocytes, electrostimulation resulted in pronuclear formation, the appearance of the 22-kDa protein, release of cortical granules, and development to the blastocyst stage. These data demonstrate that broad-spectrum inhibitors of protein kinase are unable to induce all the events associated with normal fertilization.

Ultrastructural Changes in Bovine Oocytes Cryopreserved by Vitrification

Oocytes recovered from abattoir-derived ovaries were exposed to a cryoprotectant solution (DAP213: 2 M DMSO, 1 M acetamide, 3 M propanediol, and 10% fetal calf serum in tissue culture medium 199) for less than 20 s and vitrified either at the germinal vesicle (GV) stage or after maturation in vitro (IVM). Survival was assessed by fertilization and culture in vitro to the blastocyst stage. To identify ultrastructural changes, some of the vitrified oocytes that were morphologically normal after thawing were immediately processed for transmission electron microscopy after DAP213 removal. Cleavage rates for vitrified IVM oocytes were 4.5 and 6.7% using one-step and three-step cryoprotectant dilution procedures, respectively. Four (3%) oocytes developed to the eight-cell stage with the three-step procedure, but none formed blastocysts. None of the GV oocytes cleaved, while 66.7% (78/117) of controls developed to the two-cell stage and 19.2% (15/78) of those became blastocysts. Vitrification induced profound ultrastructural modifications in microvilli, mitochondria, vesicle formation, and the ooplasm of GV oocytes, whereas these structures were generally better preserved in IVM oocytes. The integrity of cell organelles was relatively better maintained following the three-step than after the one-step procedure in both GV and IVM oocytes. Changes in the zona pellucida (ZP) of IVM oocytes due to vitrification were associated with fewer cortical granules in the ooplasm. Since previous work showed that short-term exposure to DAP213 did not cause ZP alterations in IVM oocytes, these findings suggest that ZP damage due to low temperatures may result from the premature release of cortical granules.

Competence to Undergo Normal, Fertilization-Induced Cortical Activation Develops after Metaphase I of Meiosis in Mouse Oocytes

The purpose of this study was to determine at what stage of meiotic maturation mouse oocytes develop the ability to undergo sperm-induced activation, assayed by cortical granule (CG) release. Germinal vesicle breakdown (GVBD), prometaphase I (proMI), metaphase I (MI), and metaphase II (MII, the normal stage at fertilization) stages were evaluated by quantitative image analysis. At 2 hr, fertilized MII eggs underwent a mean CG loss of 69%; loss was global—in the entire cortex occupied by CGs. In contrast, fertilized GVBD and proMI oocytes had no significant CG loss in the cortex after 2 hr. After 4 hr, 63, 67, and 88% of fertilized GVBD, proMI, and MI oocytes, respectively, had localized CG release only in the vicinity of the fertilizing sperm. At 4 hr, GVBD oocytes had small sperm-associated, CG-depleted domains, ∼100 μm2 (<1% of the oocyte cortex), whereas those for proMI oocytes were ∼2500 μm2. The CG density was reduced by 90% in these domains, whereas the remaining cortex showed no evidence of CG loss. Both the extent and time course of CG loss were altered in oocytes fertilized before MII and were not significantly affected with 25 μM thimerosal, which sensitizes egg calcium stores. Unlike the ability to undergo CG release, the ability to initiate sperm chromatin decondensation was not stage specific and the extent of decondensation was cell cycle related. Competence to undergo CG loss develops in two phases: the ability to undergo localized CG release increases between the GV and MI stages, whereas the mechanism of propagating a normal wave of global CG loss from the site of sperm entry develops between MI and MII.

Spontaneous cortical granule release and alteration of zona pellucida properties during and after meiotic maturation of mouse oocytes

Exocytosis of cortical granules (CGs) and the concomitant electron density changes of the zona pellucida (ZP) in the absence of sperm penetration were investigated in mouse oocytes processed with tannic acid containing fixation at various stages during and after maturation. After fusion of the CG membrane with the plasma membrane, the CG contents became very electron-dense, due to tannic acid. CG material is seen to be made up of coarse granular structures which gradually change to fine amorphous structures, which accumulate within the developing perivitelline space (PVS). When the coarse CG material attaches to the ZP, small domains exhibiting higher electron density appeared, and the number of these domains gradually increased. Release of CG was observed from metaphase I through metaphase II. In metaphase I to immediately after ovulation, the higher electron density of ZP and CG release was restricted to the cortical area overlying the meiotic spindle. Finally, the CG-free domain formed itself overlying the meiotic spindle as a result of CG release. However, in oviductal ova, CG release additionally occurred in the hemisphere opposite the spindle. At this stage the entire PVS was well developed and contained numerous fine electron-dense materials. Moreover, the inner half of the ZP increased in electron density as well. This change in electron density of the ZP might be associated with released CG material. These results suggest that the "partial cortical reaction" may play an important role in conditioning the ZP prior to ZP reaction.

Modifications of the mouse zona pellucida during oocyte maturation: inhibitory effects of follicular fluid, fetuin, and alpha 2HS-glycoprotein.

Mouse oocyte maturation in vivo or in vitro is accompanied by a precocious release of cortical granules. When oocytes are matured in vitro in the absence of serum, cortical granule exocytosis results in modifications of the zona pellucida (ZP) that are known to constitute the zona pellucida block to polyspermy. Fetuin, a glycoprotein found in newborn calf serum, can inhibit these maturation-associated changes in the zona pellucida. In this report we demonstrate that the human fetuin homologue, alpha 2-HS-glycoprotein, is present in human follicular fluid. Human follicular fluid, or purified human alpha 2-HS-glycoprotein, inhibits the maturation-associated conversion of mouse ZP2 to ZP2f in a concentration-dependent manner. Although the concentration of alpha 2HS-glycoprotein in human follicular fluid is high enough to account for the inhibitory effect of human follicular fluid on this maturation-associated conversion, human follicular fluid immunodepleted of alpha 2HS-glycoprotein retains its full inhibitory activity. Thus, other inhibitory molecules are likely to be present in follicular fluid and contribute to the inhibition of the maturation-associated conversion of ZP2.

Protein kinase C-dependent and independent events in mouse egg activation.

The involvement of calcium- or protein kinase C (PKC)-dependent pathways in cortical granule exocytosis (CGE) and pronucleus formation was examined in mouse eggs using the specific PKC stimulator OAG (1-oleyl-2-acetyl-sn-glycerol) at different external calcium concentrations ([Ca2+]e) ranging from 1.7 mM to 0.1 microM. A 10 min exposure of eggs to 150 microM OAG in the presence of 1.7 mM [Ca2+]e caused a large calcium influx, cortical granule release and 82% activation. The increased permeability of the egg membrane to Ca2+ ions after OAG treatment lasted 20 min. At [Ca2+]e lower than 1.7 mM, both OAG-induced calcium influx and CGE decreased, reaching a non-detectable level at 0.1 microM and 100 microM [Ca2+]e, respectively. Resumption of meiosis was not affected by [Ca2+]e above 200 microM but it was reduced at any lower [Ca2+]e, with a minimum activation frequency of 46% at 0.1 microM [Ca2+]e. Loading of eggs with > or = 3 microM of the calcium chelator BAPTA AM (1,2-bis(o-aminophenoxy)ethane-N',N',N',N'-tetraacetic acid-acetoxymethyl ester) prior to OAG treatment caused a reduction in meiosis resumption with 50% of eggs forming pronuclei. Potent inhibitors of PKC, such as acridine orange and sphingosine, did not interfere with OAG-induced CGE. Conversely, these compounds prevented OAG-induced pronucleus formation in a dose-dependent manner with an IC50 (inhibiting concentration, 50%) of 5 microM and 30 microM for acridine orange and sphingosine, respectively. Microinjection of inositol 1,4,5-trisphosphate into eggs at 0.1 microM elicited Ca2+ release from intracellular stores and the cortical reaction, but failed to stimulate pronucleus formation. These results indicate that, in mouse eggs, CGE is a PKC-independent event, and that the transition from M-phase to interphase may require PKC activity for stimulation.

Net calcium and acid release at fertilization in eggs of sea urchins and ascidians

Sea urchin eggs lose about 10–30% of their total calcium content upon fertilization. We have investigated the mechanism of this calcium-loss with an ion-selective vibrating probe system. Upon fertilization of Arbacia punctulata and Lytechinus pictus eggs we could measure a calcium efflux signal with an average duration of 204 ± 26 s and 146 ± 46 s, respectively. Measurements of hydrogen ion signals in normal and in low sodium media showed that the release of cortical vesicle material from these eggs lasts for about 30 and 50 s, respectively. The data indicate that most of the calcium that is lost from sea urchin eggs originates from the cytosol in which it is released during fertilization and then pumped out through the plasma membrane. Calcium loss due to cortical granule release accounts for less than 14% of the total loss measured. We also measured a substantial post-fertilization calcium efflux in eggs of Phallusia mammilata, with an average duration of 265 ± 18 s followed by smaller periodic effluxes that corresponded to oscillations in the [Ca 2+] i during contractile waves in these eggs. These data, together with the lack of cortical granules in ascidian eggs, indicate that Phallusia eggs also pump out a substantial amount of calcium through the plasma membrane after fertilization.

Development of pronuclei in pig oocytes activated by a single electric pulse.

Pig oocytes were matured in vitro in a modified M-199 medium for 44 h, subjected to electrical stimulation and scored for activation 6 h later. Sham pulsed oocytes, exposed to electroporation medium and an a.c. field, did not develop the female pronucleus any more frequently than occurs spontaneously (8.3% within 50 h of culture). However, a single d.c. pulse proved extremely efficient in activating pig oocytes. Pulses of 0.75-1.65 kV cm-1 lasting 30 or 100 microseconds activated at least 90% of matured oocytes. The developmental pathway taken by the activated oocytes depended on the parameters of the pulse. The lowest effective stimulation (0.45 and 0.60 kV cm-1 for 30 microseconds) frequently produced oocytes that remained in pre-pronuclear stages of activation (29.4 and 42.3%, respectively). Extrusion of the second polar body and creation of one pronucleus was the most frequent type of activation (in up to 88.2% among the activated oocytes). The strongest stimulations used (1.05-1.65 kV cm-1 for 100 microseconds) often yielded oocytes that failed to extrude the second polar body and formed two or more pronuclei (up to 56.3%). Under optimal stimulation (0.75 kV cm-1), the activated oocytes proceed synchronously to interphase of the first mitotic division. Anaphase II is reached within 30 min and telophase Ii at 1 h after application of the pulse. The second polar body is extruded about 2 h after activation. Well-defined swelling pronuclei were found in oocytes 5-6 h after activation. The relationship between the stage of oocyte maturation and susceptibility to activation was investigated. The period of culture in which the oocytes develop the activation competence (32-36 h of culture) overlapped with the period in which the oocytes complete meiosis (28-38 h). This suggests that ageing in meiotic arrest is not essential for pig oocytes to become activated by electric pulses. Activation of pig oocytes was accompanied by release of cortical granules. In sections of control (metaphase II) oocytes, an average of 7.3 intact cortical granules per 10 microns of overlying cytoplasmic membrane was found. This number dropped to 1.5 in 10 microns within 30 min after the pulse.

Fertilization failure of frozen mouse oocytes is not due to premature cortical granule release.

The proportion of mouse oocytes that were fertilized in vitro after storage at -196 degrees C in the presence of 1.5 M dimethylsulfoxide (DMSO) was significantly lower than in unfrozen controls (39% vs. 81%). Sperm failed to penetrate the zona pellucida of approximately 80% of the frozen oocytes that remained unfertilized. Removal of the zona restored fertilization to control levels, indicating that changes induced in the zona during freezing and/or thawing were the primary cause of fertilization failure. Sperm-oocyte fusion, sperm nucleus decondensation, and the resumption of meiosis in frozen oocytes appeared to be delayed but subsequently fertilization progressed normally. No evidence was found to suggest zona modification by the premature release of fucosyl-rich glycoconjugates of cortical granule origin onto the surface of the plasma membrane of frozen oocytes stained immediately after thawing with fluorescently labeled Ulex europaeus lectin. Only a few frozen (less than 5%) and control (less than 3%) oocytes that failed to fertilize in vitro had fucosylated molecules on the plasma membrane. Prolonged exposure of fertilized oocytes to DMSO at 4 degrees C did not alter the pattern of lectin binding. In conclusion, fertilization is inhibited in frozen-thawed oocytes by as yet undefined modifications to the zona pellucida which do not involve the premature release of cortical granules.

Release of tissue-type plasminogen activator by activated rat eggs and its possible role in the zona reaction.

The resumption of meiosis results in synthesis of tissue-type plasminogen activator (tPA) in the rat and mouse oocytes (Haurte et al., Cell 43:551-558, 1985). The present study demonstrates that freshly ovulated rat oocytes released their tPA into the surrounding medium upon in vitro activation by sperm penetration or treatment with a calcium ionophore. The presence of a neutralizing monoclonal anti-tPA antibody during in vitro activation by the calcium ionophore inhibited the activation-induced zona hardening and also preserved the ability of the oocyte to be penetrated by sperm subsequent to activation. Rat oocytes undergo zona hardening during in vitro maturation in the absence of serum, presumably as a result of spontaneous cortical granule release, based on findings in mice and hamsters. In the present study, the anti-tPA antibody prevented the zona hardening and enhanced partition by spermatozoa of rat oocytes that were matured in vitro without serum. Collectively, the observations reported have suggest a possible role of tPA released during the cortical granule reaction in the zona reaction, which contributes to the block to polyspermy.

Use of fetal bovine serum to protect against zona hardening during preparation of mouse oocytes for cryopreservation.

Addition of 20% fetal bovine serum (FBS) to media used for cryopreservation does not reduce the premature release of cortical granules but does prevent their action on the zona pellucida and thereby prevents zona hardening. In this paper, it is shown that the washing period required for removal of FBS is less than 12 min for cumulus-free oocytes and between 150 and 170 min for cumulus-intact oocytes. When these washing periods are observed after exposure of oocytes to the cryoprotectant dimethylsulphoxide (DMSO; 1.5 M) in the presence of 20% FBS, a subsequent exposure to calcium ionophore A23187 or a second exposure to 1.5 M DMSO both lead to zona hardening. This result suggests that sufficient cortical granules remain to elicit a block to polyspermy at fertilization. Oocytes, which had been exposed to DMSO and FBS and then washed free of both, were fertilized in vitro; the incidence of polyspermy was not found to be elevated over the level found in controls.

Modifications of the Mouse Zona Pellucida during Oocyte Maturation and Egg Activation: Effects of Newborn Calf Serum and Fetuin1

A precocious but limited loss of cortical granules (CG) occurs during mouse oocyte maturation both in vivo and in vitro. Although CG loss during maturation in vivo is not associated with changes in the zona pellucida (ZP), a maturation-associated conversion of ZP2 to ZP2f occurs during oocyte maturation in vitro in serum-free medium. We now demonstrate that a maturation-associated change of ZP3 to ZP3f, as assessed by a reduction in sperm binding, also occurs during maturation in vitro in serum-free medium, and that both newborn calf serum (NCS) and fetuin, each of which inhibits the ZP2 conversion, also inhibit the ZP3 conversion. The concentration-dependence of the NCS- and fetuin-mediated inhibition of the ZP2 conversion, coupled with the concentration of fetuin present in NCS, is consistent with fetuin being the component present in NCS that is primarily responsible for this inhibition. Although NCS can inhibit the ZP modifications that occur during oocyte maturation in vitro, ionophore treatment of eggs, which results in an extensive release of CGs over a short period of time, overcomes the inhibitory effect of NCS on the ZP2 conversion. Results of these studies suggest a potential regulatory function of serum-derived components in the formation of a fertilizable egg.

Confocal microscopy of the fertilization-induced calcium wave in sea urchins

At fertilization, the egg undergoes a rapid rise in intracellular free calcium (=[Ca2+]i), which in turn triggers several important events, including cortical granule release and metabolic activation. In sea urchins, the fertilization induced increase in [Ca2+]i begins at the site of sperm fusion and sweeps through the egg in a wavelike fashion. Whether fertilization affects calcium levels only in the peripheral ooplasm or throughout the interior of the sea urchin egg is difficult to ascertain by conventional microscopic techniques, because out-offocus rays obscure subcellular organization in these relatively bulky cells. Recently, however, confocal microscopy has been introduced as a means of producing thin optical sections that reveal details not normally discernable by conventional light microscopy. In this paper, we use confocal laser scanning microscopy (CLSM) and time-lapse reconstructions to image calcium dynamics during fertilization in living sea urchin eggs labeled with the calcium-sensitive fluorescent dye fluo-3.

Zona pellucida modifications in the mouse in the absence of oocyte activation

Mouse oocytes arrested in metaphase II exhibit zona hardening and a reduced fertilization rate after exposure to the cryoprotectant dimethylsulfoxide (Johnson J, In Vitro Fertil Embryo Transfer 6:168-175, 1989) but do not undergo parthenogenetic activation (Johnson and Pickering, Development 100:313-324, 1987). This paper shows that dimethylsulfoxide causes proteolytic modification of the zona pellucida glycoprotein ZP2 and inhibition of sperm binding. These effects of dimethylsulfoxide are caused by premature exocytosis of the cortical granules, a process that is initiated usually on fertilization. A model for the mechanism of action of dimethylsulfoxide is proposed based on the combined effects of cytoskeletal modification and osmotic shock. The presence of serum before and during the exposure to dimethylsulfoxide was found to reduce significantly these deleterious effects on the mouse zona pellucida without inhibiting the cortical granule release. These results highlight the suitability of dimethylsulfoxide as a tool to study the mechanisms leading to cortical granule release. Use of dimethylsulfoxide allows the separation of oocyte parthenogenetic activation from cortical granule release, and addition of serum allows separation of cortical granule release from the action of the cortical granule contents. Their use allows a dissection of the mechanisms underlying each of these three related events.

Localization of fucosyl glycoconjugates in human oocytes following insemination for in vitro fertilization

Human oocytes that failed to cleave after insemination were examined for the presence of fucosyl glycoconjugates in the perivitelline space by staining with Ulex europeaus lectin conjugated to fluorescein isothiocynate. Oocytes that formed two or three pronuclei following first insemination always exhibited positive lectin staining similar to that observed with in vitro fertilized mouse oocytes. Among those oocytes that failed to form any pronuclei after the first insemination attempt, only 5% contained lectin positive substances in the perivitelline space. Upon reinsemination, a higher percentage of those oocytes produced lectin-positive materials, although pronuclei were still absent. The appearance of fucosyl glycoconjugates in these oocytes might be the result of the release of cortical granules triggered by sperm penetration or, more likely, due to spontaneous granule discharge in senescent oocytes.

Problems in the cryopreservation of unfertilized eggs by slow cooling in dimethyl sulfoxide

The survival, fertilization, development, and viability in vitro and in vivo of unfertilized mouse eggs frozen by slow cooling to –36°C or –80°C in 1.5M dimethyl sulphoxide (DMSO) was examined in a series of experiments which explored some of the problems in freezing the egg. DMSO was added to the eggs at either room temperature or at 0°C. Maximum success rate (42% of frozen eggs developing to two cells) was obtained when DMSO was added at 0°C and the eggs slow cooled to –80°C. Removal of cumulus failed to improve freezing success rates. Addition of DMSO at temperatures above 0°C significantly reduced the fertilizing capacity of eggs. Excessive exposure of eggs to temperatures around 15°C also caused a significant reduction in fertilization rates. The effects of DMSO and cooling on fertilization are likely to be due to zona hardening by cortical granule release and to disorganization of the egg cytoskeleton and plasma membrane. These problems will be difficult to overcome if cryopreservation of the unfertilized human egg is preferred to the fertilized egg or early cleavage stage embryo in clinical in vitro fertilization.

The influence of cooling on the properties of the zona pellucida of the mouse oocyte.

Mouse oocytes were exposed to a variety of cooling regimes prior to insemination in vitro. Exposure to 4 degrees C, but not to 25 degrees C, was associated with a reduced fertilization rate, but development to the blastocyst stage of those oocytes that fertilized was not consistently different from that of non-cooled controls. The reduced fertilization rate seems to result from an effect of cooling on the zona pellucida, since it was not observed if the zona was removed prior to insemination, and since cooling rendered the zona pellucida resistant to the action of chymotrypsin. Using chymotrypsin resistance as an assay, the nature of the cooling-induced effect on the zona was investigated. It is suggested that rapid cooling to 4 degrees C may promote release of cortical granules and a premature zona reaction.

The appearance of glycoconjugates associated with cortical granule release during mouse fertilization.

For the first time we have shown with appropriately labelled lectins that fucosyl- and sialyl-rich glycoconjugates are released into the perivitelline space of the mouse oocyte after activation by the fertilizing spermatozoon or artificial activation by the calcium ionophore A23187 or ethanol. The glycoconjugates show a punctate distribution over the oocyte surface except for the microvilli-free area overlying the second meiotic spindle from which they are absent. Their appearance in the perivitelline space is associated with the release of the cortical granule suggesting that they represent part of the cortical granule exudate. Soon after the glycoconjugates appear, they begin to aggregate. The process continues until the beginning of cytokinesis at first cleavage when a single large aggregate is found within the cleavage furrow. Most of the labelled glycoconjugates disappear by the late 2-cell stage and no evidence was found for their presence during the later preimplantation period. This technique is suitable for monitoring the kinetics of the cortical reaction in mammalian oocytes and investigating the importance of the glycoconjugates in early preimplantation period.