Differential Emergence of Cortical Granule Breakdown and Electrophysiological Responses during Meiotic Maturation of Toad Oocytes

Oocytes of the toad, Bufo bufo japonicus , at various stages of progesterone-induced maturation were stimulated by pricking or treatment with Ca-ionophore A23187. Upon pricking, oocytes 14 hr after hormone treatment (PHT) underwent sequential activation responses, such as development of an activation potential, cortical granule breakdown (CGBD), and formation of a perivitelline space (PVS), like those of mature oocytes (18 hr PHT). When oocytes were pricked at 14 hr PHT, it took about 10 min for the wave of CGBD to spread over all the oocyte surface, in contrast to the case with mature oocytes in which it took about 150 sec. The rate of spread of CGBD was significantly less in the vegetal hemisphere than in the animal hemisphere in both mature and immature oocytes. Treatment with A23187 (1 μM) for 5 min induced an activation potential, and PVS formation by the oocytes from 10 hr PHT, which was 3–4 hr earlier than the time when these responses could be induced by pricking. Oocytes at 8–9 hr PHT also showed CGBD in response to A23187, but without formation of an activation potential. Several patches of local PVS caused by the non-propagating CGBD were observed in oocytes treated with the ionophore 5–7 hr PHT. When a high concentration (10 μM) of A23187 was employed, CGBD without PVS formation was induced even in oocytes at 0 hr PHT. These results indicate that the responsiveness to a Ca²⁺ surge that is a prerequisite for both CGBD and genesis of an activation potential is acquired for the repective responses at different stages of oocyte maturation.     

Precocious induction of activation responses in amphibian oocytes by divalent ionophore A23187

Temporal relationships between maturational events and the onset of activation in response to divalent ionophore and to pricking were examined following in vitro exposure of Rana pipiens oocytes to desoxycorticosterone acetate (DOCA). Activation was evaluated on the basis of vitelline envelope elevation and cortical granule breakdown. Ionophore-induced activation was first observed after 18 hr of DOCA incubation, coincident with the time of separation of the vitelline envelope from the oocyte surface and 2–3 hr after breakdown of the germinal vesicle. Activation in response to pricking was not observed until 30 hr of DOCA incubation. Neither ionophore treatment nor pricking resulted in activation of oocytes that had not been incubated with DOCA. These results indicate that oocytes can be activated many hours earlier than previously demonstrated. The time of onset of the capacity for activation appears to be related to germinal vesicle breakdown and vitelline envelope separation.     

APPEARANCE OF PRONUCLEUS-INDUCING ACTIVITY DURING HORMONALLY INDUCED MEIOTIC MATURATION IN TOAD OOCYTES*

Detergent-pretreated spermatozoa of the toad, Bufo bufo japonicus, transform into pronuclei when injected into progesterone-matured oocytes at 18 hr post-hormone treatment (PHT). These sperm, however, do not show any change when injected into the oocytes at the same age from which the germinal vesicle (GV) has been removed before the progesterone treatment. In an attempt to determine when and how the pronucleus-inducing activity (PIA) develops in hormonally induced maturation process, enucleated oocytes were injected with GV and sperm at various stages after the hormone treatment and electrically stimulated at 18 hr PHT. It was found that sperm pronuclei are induced only in those oocytes receiving GV before 14 hr PHT. The 1 hr pulse-treatment of maturing oocytes with cycloheximide between 8–18 hr PHT and the injection of sperm at 18 hr PHT revealed that PIA does not occur in the oocytes treated with the inhibitor during 10–14 hr PHT. Injection of α-amanitin into maturing oocytes had no effect in this respect. Determination of DNA synthetic activity in vitro of the oocyte extracts from various maturation stages showed that the net increase of the activity occurs before the formation of PIA. The activity of the cycloheximide-treated oocyte extracts utilizing native DNA did not correlate with the sensitivity of oocytes to the inhibitor with respect to PIA in situ. It is concluded that PIA develops, in association with the GV materials, by way of translational events at 10–14 hr PHT, being quiescent during later maturation stages, and commences to function as an activation response of oocytes at 18 hr PHT.     

Formation of the cortical reaction in the process of oocyte maturation in the starred sturgeon]

The chronology of maturation process and cortical reaction development was studied in the Volga sevryuga oocytes. The germinal vesicle breakdown was first noted at 14 tau 0 following the injection of hypophysial suspension to the female and observed in the vast majority of oocytes at 17 tau 0; different phases of the I maturation division were found at 21 to 25 tau 0 and metaphase II at 33 tau 0. The ability to respond by cortical reaction to the activating stimulus (glass needle pricking) was first observed at 17 tau 0, i.e. soon after the germinal vesicle breakdown, but the appearance of the ability for cortical reaction was not connected causatively with the latter process. The cortical reaction in the maturing oocytes (17 to 25 tau 0) is characterized by the following features: in some oocytes the rate of the wave of granule breakdown is much lower than in the mature eggs; in ca. 80% of oocytes with the normal rate of cortical reaction the process of release of the contents of cortical granules in inhibited in the animal pole region and accordingly the contact of cytoplasm with the membranes is preserved in this region for a long time.     

The effect of trifluoperazine on maturation of Xenopus laevis oocytes

Full grown Xenopus oocytes were incubated with trifluoperazine (TFP) or injected with TFP. Incubation of oocytes in TFP resulted in normal-appearing meiotic maturation, as judged by the presence of the white spot and the absence of the germinal vesicle. Cortical granule breakdown in TFP-incubated oocytes was not normal. Abnormal cortical granule breakdown was also observed when progesterone-maturated oocytes were activated in the presence of TFP. Oocytes microinjected with TFP and incubated with progesterone appeared to mature in a normal manner, as judged by the absence of the germinal vesicle; these underwent cortical granule breakdown following activation, but frequently lacked the white spot. Oocytes microinjected with TFP did not mature in the absence of progesterone. We conclude that incubation, although not microinjection, of oocytes with TFP induces essentially normal resumption of meiotic maturation.     

Nuclear requirement of post-maturational cortical differentiation of amphibian oocytes: effects of cycloheximide.

Cycloheximide induced a complex series of alterations in the cortical cytoplasm of amphibian (Rana pipiens) oocytes undergoing steroid induced nuclear and cytoplasmic maturation in vitro. The morphological changes were described and the role of nuclear-cytoplasmic interactions in the induction of these changes was investigated in intact, enucleated and enucleated-reinjected oocytes. Three stages of cortical changes were ascertained on the basis of: localized alterations at the animal pole, redistribution of pigment and localized contractility (furrow formation) primarily along the animal:vegetal pole axis. The extent and type of cortical alterations varied depending upon the time at which oocytes were examined following hormonal stimulation and cycloheximide treatment. Cycloheximide did not produce cortical alterations in non-hormone treated oocytes nor in steroid treated oocytes until after germinal vesicle breakdown. Nuclear and cytoplasmic maturation and the appearance of cortical alterations were all inhibited when cycloheximide was added to oocytes at the time of steroid treatment. Cycloheximide induction of cortical alterations occurred only after the inhibitor was no longer effective in preventing germinal vesicle breakdown. Enucleated oocytes underwent cytoplasmic maturation in response to the steroid but exhibited no cortical alterations following the delayed addition of cycloheximide. Simultaneous administration of cycloheximide and steroid to enucleated oocytes inhibited cytoplasmic maturation and all observable cortical alterations. Reinjection of nuclear material into enucleated oocytes restored the ability of cycloheximide to induce cortical alterations following steroid induction of cytoplasmic maturation. Without steroid treatment, such reinjected oocytes did not exhibit cortical changes in response to cycloheximide. The data demonstrate that the nucleus is required for and contains a factor(s) which controls the cycloheximide response and post-maturation differentiation of the oocyte. The maturational changes in the cortical cytoplasm appear to be dependent on the intermixing of the germinal vesicle nucleoplasm materials with mature cytoplasm following germinal vesicle breakdown. The results further suggest that the cortical effects of cycloheximide are dependent upon the initiation of protein synthesis during this period of oocyte development. The significance of these observations and experimental studies are discussed in relation to current understanding of the molecular mechanisms controlling meiosis induction and the composition of the germinal vesicle.     

Maturation of Xenopus oocytes: II. Observations on membrane potential

Large, progesterone-responsive oocytes within their follicles have an average resting potential of about ?25 mV. When manually dissected out of their follicles, most of these oocytes undergo a hyperpolarization over the next 30–60 min to values of about ?60 to ?80 mV. The relatively high negative membrane potentials previously recorded on dissected amphibian oocytes may thus be an artifact in the sense that such measurements do not reflect the electrical characteristics of the oocyte within the follicle. The available evidence indicates that the hyperpolarization reflects the activation of an electrogenic Na⁺,K⁺-transport process. One of the terminal events of oogenesis appears to be a suppression of the generation of the Na⁺,K⁺-transport process when oocytes are ovulated artificially (by dissection) or naturally. Continuous, long-term recordings on dissected oocytes reveal that a rather pronounced depolarization of the membrane potential together with an inflection in the recorded potential around the time of germinal vesicle breakdown takes place in the presence of progesterone. Recordings of oocytes within the follicle reveal similar changes, although reduced in absolute magnitude. In both cases, final membrane potentials of ?10 to ?15 mV are achieved. The electrophysiological changes which accompany the normal maturation process thus do not appear to be as pronounced as previously indicated.     

Induction and Inhibition of Meiotic Maturation in Follicle-enclosed Mouse Oocytes by Forskolin

A continuous exposure of follicle-enclosed mouse oocytes to ovine luteinizing hormone (LH, 10 μg/ml) in vitro resulted in a 3-fold elevation of CAMP levels in the follicle cells, but not the oocytes, with subsequent oocyte maturation. When follicle-enclosed oocytes were exposed to forskolin (0.01–10 μM) for 2 hr and then incubated in forskolin-free medium (transient exposure group), oocytes underwent germinal vesicle breakdown in a dose-dependent manner. In contrast, a continuous exposure of the follicles to forskolin (10 μM) for up to 10 hr failed to induce resumption of meiosis. Follicle cell cAMP levels increased within 2 hr after the initial exposure to forskolin, and thereafter decreased rapidly regardless of whether forskolin treatment was transient or continuous. A similar transient increase in oocyte cAMP levels was observed after transient or continuous treatment with forskolin. It was evident, however, that at any time examined oocyte cAMP levels were consistently higher in the continuous exposure group than in the transient exposure group. Furthermore, a continuous exposure to forskolin also blocked LH-induced meiotic maturation. These findings suggest that elevated levels of cAMP in the oocyte block meiotic maturation in mouse oocytes. The present results further suggest that an increase in follicle cell cAMP levels is essential to the LH-induced meiotic maturation.     

Active maturation-promoting factor is present in mature mouse oocytes

Cytoplasmic extracts of meiotically mature mouse oocytes were injected into immature Xenopus laevis oocytes, which underwent germinal vesicle breakdown within 2 h. Germinal vesicle breakdown was not inhibited by incubation of the Xenopus oocytes in cycloheximide (20 micrograms/ml). Identically prepared extracts of meiotically immature mouse oocytes, arrested at the germinal vesicle stage by dibutyryl cyclic AMP (100 micrograms/ml), did not induce germinal vesicle breakdown in Xenopus oocytes. The results show that maturation-promoting factor activity appears during the course of oocyte maturation in the mouse.     

Changes in membrane hydrogen and sodium conductances during progesterone-induced maturation of Ambystoma oocytes

A voltage-gated hydrogen ion-selective conductance has been previously described in the immature oocyte of the urodele amphibian Ambystoma. The present study was prompted by reports that changes in membrane voltage and internal pH, as well as in internal sodium ion concentration, occur during the hormone-induced maturation of oocytes from other amphibians. As activation of membrane currents might mediate changes in internal ion concentrations in addition to altering the membrane voltage, microelectrode recording techniques have been employed to examine changes in membrane conductances which occur during maturation of Ambystoma oocytes. It was observed that during the first 5 hr of maturation the magnitude of the hydrogen ion conductance gradually decreased, and that subsequently there was an increase in the amplitude of a voltage-dependent noninactivating sodium conductance. After 6 to 7 hr, after the loss of the hydrogen conductance and at about the time of germinal vesicle breakdown, the resting potential of the oocyte spontaneously shifted from approximately -10 mV to approximately +30 mV, where it remained until at least 24 hr after the initiation of maturation. This voltage transition was due to the appearance of mechanisms generating inward current in the oocyte membrane; part of this inward current was due to the tonic activation of the sodium conductance. Changes in internal pH and internal sodium ion concentration occurred during maturation, as judged from shifts in the reversal potentials of both hydrogen and sodium currents. A gradual decrease in internal hydrogen ion concentration was observed up until the time of disappearance of the hydrogen conductance (change in internal pH from about 7.15 in immature oocytes to about 7.40 by 3 hr after application of progesterone). This was followed, as sodium conductance increased, by an apparent rise in the internal sodium ion concentration (from about 6 mM to about 17 mM by 10 hr postprogesterone).     

Thein vitro effect of theophylline on 17α, 20ß-dihydroxy-4-pregnen-3-one-induced germinal vesicle breakdown in the catfish,Clarias batrachus

The effects of theophylline (a phosphodiesterase inhibitor) and cAMP on 17α, 20ß-dihydroxy-4-pregnen-3-one-induced germinal vesicle breakdown was investigatedin vitro in catfish (Clarias batrachus) oocytes. Folliculated oocytes incubated with 17α, 20ß-dihydroxy-4-pregnen-3-one at the concentration of 1 μg/ml induced 93.2 ± 2.23% germinal vesicle breakdown. When the oocytes were prestimulated with 17α,20ß-dihydroxy-4-pregnen-3-one for 6 h and then treated with different concentrations of theophylline, there was a significant drop in the frequency of germinal vesicle breakdown at the concentrations 2.0, 1.5 and 1.0 mM. However, theophylline was found to be incapable of inhibiting germinal vesicle breakdown at its lowest concentration (0.5 inM). In the time course study, significant inhibition of germinal vesicle breakdown was recorded when 1 mM theophylline was added up to 30 h of 17α,20ß-dihydroxy-4-pregnen-3-one Stimulation but the inhibitory effect of theophylline gradually (time dependent manner) declined if the stimulatory time of 17α,20ß-dihydroxy-4-pregnen-3-one was increased. A similar inhibition of germinal vesicle breakdown was also recorded with various concentrations of cAMP. Except 0.5 mM, all the higher concentrations of cAMP significantly inhibited 17α,20ß-dihydroxy-4-pregnen-3-one induced germinal vesicle breakdown.     

Requirement for glucose in ligand-stimulated meiotic maturation of cumulus cell-enclosed mouse oocytes.

In this study, the effect of different energy sources used in Eagle's minimum essential medium on the meiotic maturation of mouse oocytes in culture was examined. The effects of glucose (5.5 mmol 1(-1)), pyruvate (0.23 mmol 1(-1)) and glutamine (2 mmol 1(-1)) in different combinations were tested on the maturation of denuded oocytes in the presence or absence of 300 mumol dibutyryl cAMP 1(-1) during 17-18 h of culture. In the absence of cyclic nucleotide, only oocytes from those groups containing pyruvate resumed maturation at a high frequency (99-100% germinal vesicle breakdown); all other combinations resulted in < or = 54% germinal vesicle breakdown. When dibutyryl cAMP was introduced, all pyruvate-containing groups exhibited maturation frequencies of about 50%, whereas maturation in all other groups was negligible (< or = 10% GVB). Pyruvate was also important for the maintenance of viability in denuded oocytes (> or = 86% viability in pyruvate-containing medium; < or = 35% viability in pyruvate-free groups). When cumulus cell-enclosed oocytes were cultured in medium without inhibitor, all combinations of energy substrates supported high frequencies of maturation (> or = 89% germinal vesicle breakdown) and viability (> or = 91%). The addition of dibutyryl cAMP resulted in inhibition of meiotic maturation (5-33% germinal vesicle breakdown) in all cultures except the pyruvate-alone group (97% germinal vesicle breakdown). Viability in cumulus cell-enclosed oocytes was greatest when two or more energy substrates were present in the medium. Follicle-stimulating hormone (FSH) produced a stimulation of meiotic maturation in all cultures of meiotically arrested cumulus cell-enclosed oocytes, but maximal induction of germinal vesicle breakdown was dependent upon D-glucose. Concanavalin A (ConA)-induced meiotic maturation was also dependent upon D-glucose. Uptake and metabolism of D-glucose by the cumulus cells is important in mediating the stimulatory effects of these ligands on oocyte maturation because (1) both FSH and ConA stimulated uptake of D-glucose and 2-deoxyglucose but not 3-O-methylglucose; (2) phloretin prevented the stimulatory action of FSH and ConA on germinal vesicle breakdown at a concentration that suppressed ligand-induced uptake of D-glucose; (3) 2-deoxyglucose, a hexose that suppresses glycolysis, prevented the induction of meiotic maturation by FSH and ConA and (4) D-mannose, a glycolysable sugar, was as effective as D-glucose in supporting the ligand effects.(ABSTRACT TRUNCATED AT 400 WORDS)     

FORMATION OF THE FERTILIZATION MEMBRANE BY INSEMINATION OF IMMATURE STARFISH OOCYTES PRETREATED WITH CALCIUM-FREE SEAWATER

When immature oocytes of the starfish, Asterina pectinifera , were treated with calcium-free seawater for 1 hr and then inseminated in normal seawater, they formed several blisters, indicative of polyspermy, and raised fertilization membranes. These oocytes continued to have intact germinal vesicles. Electron microscopic study revealed that the egg surface remained virtually unchanged after the treatment with calcium-free seawater. Upon insemination, however, the cortical granules broke down and the fertilization membrane was formed. These immature oocytes with ferilization membranes underwent maturation (germinal vesicle breakdown) after treatment with 1-methyladenine.
The treatment with calcium-free seawater seems to bring about some physiological change on the surface of immature oocyte, which bestows some attributes of maturation but is insufficient to mature the oocytes completely.     

中华大蟾蜍卵母细胞成熟过程中膜电位变化的实验分析

The full-grown oocytes obtained from toad (bufo bufo gargarizans) submitted in hibernation state or reared at 25-30 degrees C for several months, named hibernation oocyte or high temperature oocyte, had a membrane potential of -41.51 +/- 0.77 mV and -43.83 +/- 1.39 mV in Ringer's solution respectively. The hibernation oocytes underwent GVBD (germinal vesicle breakdown) and membrane depolarization at 19 +/- 1 degree C after progesterone stimulation. The membrane potential was about -20 mV at the period of GVBD, and -10 mV or so at 20 hours after the hormone treatment. However, the high temperature oocytes did not undergo GVBD, their membrane potential decreased before the fourth hour after treatment with progesterone and then recovered. If the hibernation oocytes were preincubated at 37-38 degrees C for 13 hours prior to the culture in the medium containing progesterone (10(-6)M, 37-38 degrees C), no GVBD was observed and the membrane depolarized before the fourth hour after treatment with progesterone then recovered, but MPF was detectable in the cytoplasm (unpublished). Both GVBD and membrane depolarization appeared in the hibernation oocytes and high temperature oocytes after injection of MPF. The time required for the hibernation oocytes injected MPF to attain the membrane potential about -20 mV was 4 hours earlier than that of progesterone treatment. It was just the time required for the appearance of MPF in the cytoplasm of oocytes treated with the hormone. It was noticed in our precedent article that a factor which appeared in the cytoplasm of high temperature oocytes differed from MPF. The factor was called Hibernation Oocyte Mature Promoting Factor (HOMPF).(ABSTRACT TRUNCATED AT 250 WORDS)     

In vitro facilitation of Xenopus oocyte maturation by subthreshold doses of progesterone

Following progesterone treatment, a significant lag (4–8 hr) in the induction of germinal vesicle breakdown (GVBD) is observed in amphibian oocytes. Preincubation of Xenopus oocytes in the presence of subthreshold doses of progesterone decreases the lag (1–3 hr) and, therefore, facilitates oocyte maturation. Progesterone facilitation of GVBD is a dose-dependent reversible phenomenon. On the other hand, it is also reported that cyclic-AMP phosphodiesterase inhibitors increase the lag (8–15 hr) between progesterone stimulation and germinal vesicle breakdown.     

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.     

Sperm-derived activating ability does not persist in mouse oocytes inseminated during in vitro maturation

Activity of the sperm-derived oocyte-activating factor persists in zygotes and can be detected by a fusion with metaphase II (MII) oocytes leading to the activation of the hybrids. We have shown, that in the great majority of oocytes inseminated 1-2 hr after germinal vesicle breakdown (GVBD) the sperm-derived activating ability was eliminated. Only few hybrids produced by fusion of MII oocytes with oocytes inseminated during in vitro maturation (M x IVM-P + sperm hybrids) underwent activation, whereas almost all of MII oocyte x zygote hybrids entered interphase. However, frequency of activation of M x IVM-P + sperm hybrids was higher than that of control hybrids, which were obtained by fusion of MII oocytes with oocytes uninseminated during in vitro maturation. Although the difference was not statistically significant, it suggested that in a certain number of oocytes inseminated after GVBD the sperm-derived oocyte-activating factor remained partially active. This was confirmed by our observation that several oocytes, which were inseminated during in vitro maturation and managed to accomplish MII, underwent activation and formed pronuclei when examined 25-26 hr after the beginning of maturation. We have also demonstrated that parthenogenotes, could acquire the sperm-derived activity, as a consequence of sperm injection. MII oocytes were fused with parthenogenotes inseminated by ICSI and all hybrids underwent activation. This result indicated that the ability to induce activation in hybrid, was sperm-derived.     

Mitogen activated protein kinase plays a significant role in metaphase II arrest, spindle morphology, and maintenance of maturation promoting factor activity in bovine oocytes

Mammalian oocytes are arrested at the G2/M transition of the first meiotic division from which, after reaching full size and subsequent to an LH surge, they undergo final maturation. Oocyte maturation, which involves germinal vesicle breakdown, progression through metaphase I (MI), and arrest at MII, is triggered and regulated by the coordinated action of two kinases, maturation promoting factor (MPF) and mitogen activated protein kinase (MAPK). The importance of the role of MPF in mammalian oocyte maturation is well established, while the role of MAPK, although well understood in mouse oocytes, has not been fully elucidated in oocytes of large domestic species, especially bovine oocytes. Here we show that injection of MKP-1 mRNA, which encodes a dual specificity MAPK phosphatase, into germinal vesicle stage bovine oocytes prevents the activation of MAPK during maturation. Despite the lack of MAPK activity, MKP-1-injected oocytes resume and progress through meiosis, although they are unable to arrest at MII stage and, by 22-26-hour post-maturation, exhibit decondensed pronucleus-like chromatin, a clear sign of parthenogenetic activation. MKP-1-injected bovine oocytes exhibit normal activation of MPF activity; however, by 18-hour post-maturation, MPF activity starts to decline and by 22-26 hr MPF activity is absent. MKP-1-injected oocytes also show disorganized MII spindles with poorly aligned chromosomes. In summary, our results demonstrate that in bovine oocytes MAPK activity is required for MII arrest, maintenance of MPF activity, and spindle organization.     

Bovine oocytes treated prior to in vitro maturation with a combination of butyrolactone I and roscovitine at low doses maintain a normal developmental capacity.

Butyrolactone I (BL-I) and Roscovitine (ROS), two specific and potent inhibitors of M-phase promoting factor (MPF) kinase activity, were used to block germinal vesicle breakdown (GVBD) of cattle oocytes. A concentration 6.25 microM BL-I and 12.5 microM ROS blocked over 93.3 +/- 2.5% of oocytes in germinal vesicle (GV) stage during a 24-hr culture period. Following a second 24-hr culture step in maturation medium (IVM) almost all (91.5 +/- 3.0%) inhibited oocytes resumed meiosis and reached the metaphase II (MII) stage. The MII kinetics was different for inhibited and control oocytes. Fifty percent MII was reached at 13-14 hr in BL-I + ROS treated oocytes, compared to 18 hr in control oocytes. Therefore, control oocytes were fertilised (IVF) after 22 hr IVM and inhibited oocytes after 16 or 22 hr IVM. After IVF, percentage of grade 1 freezable embryos on day 7 (D + 7) as well as percentage of blastocyst formation on D + 8 in the group of BL-I + ROS treated oocytes fertilised after 16 hr IVM were higher (P < 0.05) compared with the other experimental group fertilised after 22 hr IVM but not different in comparison with the control. Survival to freezing and thawing of grade 1 embryos frozen on D + 7 was employed as viability criteria and was similar in all groups. Thus, the presence of BL-I + ROS in the prematuration medium of bovine oocytes determines a reversible meiotic block, without compromising their subsequent developmental competence.     

Cyclic assembly-disassembly of cortical microtubules during maturation and early development of starfish oocytes

An extensive array of cortical microtubules in oocytes of the starfish Pisaster ochraceus undergoes multiple cycles of disappearance and reappearance during maturation and early development. These events were studied in isolated fragments of the oocyte cortex stained with antitubulin antibodies for indirect immunofluorescence. The meshwork of long microtubules is present in the cortex (a) of immature oocytes, i.e., before treatment with the maturation-inducing hormone 1-methyladenine, (b) for 10-20 min after treatment with 1-methyladenine, (c) after formation of the second polar body (in reduced numbers in unfertilized oocytes), and (d) in the intermitotic period between first and second cleavage divisions. The array of cortical microtubules is absent in oocytes (a) undergoing germinal vesicle breakdown, (b) during the two meiotic divisions (polar body divisions), and (c) during mitosis of the first and, perhaps, subsequent cleavage divisions. The cycle of assembly-disassembly of cortical microtubules is synchronized to the cycle of nuclear envelope breakdown and reformation and to the mitotic cycle; specifically, cortical microtubules are present when a nucleus is intact (germinal vesicle, female pronucleus, zygote nucleus, blastomere nucleus) and are absent whenever a meiotic or mitotic spindle is present. These findings are discussed in terms of microtubule organizing centers in eggs, possible triggers for microtubule assembly and disassembly, the eccentric location of the germinal vesicle, and the regulation of oocyte maturation and cell division.