Deep cytoplasmic rearrangements during early development in Xenopus laevis

The egg of the frog Xenopus is cylindrically symmetrical about its animal-vegetal axis before fertilization. Midway through the first cell cycle, the yolky subcortical cytoplasm rotates 30 degrees relative to the cortex and plasma membrane, usually toward the side of the sperm entry point. Dorsal embryonic structures always develop on the side away from which the cytoplasm moves. Details of the deep cytoplasmic movements associated with the cortical rotation were studied in eggs vitally stained during oogenesis with a yolk platelet-specific fluorescent dye. During the first cell cycle, eggs labelled in this way develop a complicated swirl of cytoplasm in the animal hemisphere. This pattern is most prominent on the side away from which the vegetal yolk moves, and thus correlates in position with the prospective dorsal side of the embryo. Although the pattern is initially most evident near the egg's equator or marginal zone, extensive rearrangements associated with cleavage furrowing (cytoplasmic ingression) relocate portions of the swirl to vegetal blastomeres on the prospective dorsal side.     

Intracellular localization of argyrophilic proteins in the maturing oocyte,fertilized egg,and spermatozoa of the starfish,Asterina pectinifera

Changes in intracellular localization of argyrophilic proteins visualized as silver-stained particles by nuclear organizer region (NOR)-silver staining were investigated in starfish oocyte maturation. The silver-stained particles were localized in the germinal vesicle and nucleolus of immature oocytes and dispersed into the cytoplasm at the time of germinal vesicle breakdown (GVBD). In the mature egg cytoplasm, silver-stained particles were distributed on yolk-like granules with diameters of 0.3–1.0 μm. In spermatozoa, silver-stained particles were detected heavily in the acrosome and centrosomes but few were detected in the nucleus, whereas they were present in the male pronucleus of fertilized eggs. The silver-stained particles were removed by pretreatment of eggs with protease but not with nuclease. These results indicate that argyrophilic proteins disperse to the egg cytoplasm during GVBD and might be incorporated to the male pronucleus from the egg cytoplasm in fertilization. The morphological changes from chromosomes through chromosome vesicles to female pronucleus were also observed with light microscopy after NOR-silver staining.     

Premature sperm incorporation into the primary oocyte of the polychaete Pectinaria: Male pronuclear formation and oocyte maturation

Immature oocytes of the annelid Pectinaria were prematurely fertilized while in the germinal vesicle stage. Fertilization was morphologically normal except for the formation of an enlarged fertilization cone which persisted even after sperm incorporation. However, at 30 min postinsemination, no signs of male pronuclear morphogenesis were detected. Ultrastructural data show that in the cytoplasm of a GV-stage oocyte the sperm nuclear envelope remains intact and the enclosed chromatin remains condensed. Prematurely fertilized eggs were then induced to undergo germinal vesicle breakdown (GVBD). Subsequently male pronuclear development occurred. Thus, the factors in the Pectinaria oocyte which are necessary for sperm transformation develop in the maturing cytoplasm and are dependent upon GVBD. Such prematurely fertilized oocytes fail to display the normal arrest of meiosis at Metaphase I, but instead progress directly to formation of the female pronucleus. Occurrences of normal first cleavage were observed suggesting that prematurely incorporated sperm can be recruited for participation in development.     

The role of the germinal vesicle in producing maturation-promoting factor (MPF) as revealed by the removal and transplantation of nuclear material in starfish oocytes

In starfish, oocytes are released from prophase block by a hormone, which has been identified as 1-methyladenine. The action of 1-methyladenine is indirect in inducing oocyte maturation: it acts on the oocyte surface to produce a cytoplasmic maturation-promoting factor (MPF), the direct trigger of germinal vesicle breakdown (GVBD). Less than 5 min after hormone addition, thus about 10 min before appearance of the cytoplasmic maturation-promoting factor, a factor appears in the germinal vesicle, which triggers the production of cytoplasmic MPF, GVBD, and the subsequent events of meiotic maturation when transferred in the cytoplasm of any fully grown oocyte of the starfishes Marthasterias glacialis and Asterias rubens. Before hormone action, the germinal vesicle also contains a factor capable of inducing meiosis reinitiation in recipient oocytes, but in contrast with nuclear MPF, this factor acts exclusively when transferred in the cytoplasm of a special category of oocytes (the “competent” oocytes). In contrast to other oocytes (the “incompetent” oocytes) the competent oocytes are capable of producing MPF to some extent after enucleation, upon hormonal stimulation. Transfer of either nuclear or cytoplasmic MPF initially produced in hormone-treated maturing oocytes triggers the production of both cytoplasmic and nuclear MPF in non-hormone-treated recipient oocytes of both categories.     

Control of chromosome behavior in amphibian oocytes. I. The activity of maturing oocytes inducing chromosome condensation in transplanted brain nuclei

The capability of oocyte cytoplasm to induce chromosome condensation was studied by transplantation of isolated brain nuclei into Rana pipiens oocytes induced to undergo maturation in vitro by progesterone treatment. It was found that the chromosome condensation activity (CCA) first appeared in the cytoplasm of maturing oocytes shortly after germinal vesicle breakdown (GVBD), persisted in fully mature oocytes, but rapidly disappeared when the oocytes were artificially activated. A comparison of the time course of the oocyte chromosome condensation cycle and of brain chromosome condensation in maturing and activated oocytes revealed a close temporal correlation between the two, suggesting that both are under the control of the same cytoplasmic factor(s). Oocytes enucleated before GVBD always failed to develop CCA. The CCA could be restored in enucleated oocytes by injecting nucleoplasm obtained from oocytes that had not yet undergone GVBD although this same nucleoplasm was incapable of producing CCA when mixed with the cytoplasm of oocytes that had not reached the stage of GVBD. It was therefore suggested that the CCA had a dual origin involving both cytoplasmic maturation and GV materials.     

Effects of cycloheximide on a cytoplasmic factor initiating meiotic maturation in Xenopus oocytes

Oocytes induced to undergo meiotic maturation by progesterone possess a cytoplasmic activity that causes germinal vesicle breakdown (GVBD). The cytoplasmic factor postulated to be responsible for this activity is designated as the maturation promoting factor (MPF). The activity of MPF was assayed by injecting cytoplasm into fully-grown oocytes to induce GVBD. It was found that maturing oocyte cytoplasm possesses MPF activity before GVBD begins. Treatment of progesterone stimulated oocytes with cycloheximide, either applied externally or injected, inhibited the appearance of MPF in the cytoplasm as well as GVBD when the inhibitor treatment was initiated before the cytoplasm exhibited MPF activity. In contrast, the same treatment did not inhibit GVBD when it was applied to oocytes after the cytoplasm possessed MPF activity. Furthermore, cycloheximide treatment of recipient oocytes did not inhibit the induction of GVBD by injected cytoplasm containing MPF. Cytoplasm of oocytes injected with MPF subsequently possessed MPF activity as high as that of the original donor cytoplasm in spite of its extensive dilution. This suggests that amplification of MPF took place in the recipient. Cycloheximide treatment did not inhibit the amplification of MPF. It was concluded that cycloheximide inhibits only the initial phase of induction of MPF activity, but neither its amplification nor its action on the nucleus that causes GVBD. From these results, a hypothesis concerning the cytoplasmic mechanism for the induction of GVBD has been proposed.     

Induction of starfish oocyte maturation by the beta gamma subunit of starfish G protein and possible existence of the subsequent effector in cytoplasm.

beta gamma subunits of G proteins were purified from starfish oocytes, and their role in the induction of oocyte maturation by 1-methyladenine was investigated. When injected into starfish oocytes, the purified beta gamma subunit of the starfish G protein induced germinal vesicle breakdown (GVBD) faster than that of bovine brain G protein. Injection of the starfish beta gamma into cytoplasm near the germinal vesicle (GV) induced GVBD earlier than when injected into the GV or the cytoplasm near the plasma membrane. Fluorescent-labeled beta gamma was retained in the injected area even after GVBD. Injected beta gamma also induced the formation of maturation-promoting factor as well as an increase of histone H1 kinase activity. These results suggest that beta gamma dissociates from alpha-subunit by the stimulation of 1-methyladenine and interacts with a cytoplasmic effector, which results in formation of active cdc2 kinase.     

Possible involvement of calmodulin in maturation and activation of Chaetopterus eggs

We report the isolation of calmodulin from oocytes of Chaetopterus pergamentaceus. The identification of this protein is based on (1) activation of beef heart cAMP phosphodiesterase, (2) heat stability, (3) sensitivity to chlorpromazine, and (4) electrophoretic mobility identical to that of porcine brain calmodulin after sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence of either Ca2+ or EGTA. We treated oocytes with chlorpromazine and W-7 to investigate the involvement of calmodulin in meiosis initiation and egg activation. Very low concentrations of chlorpromazine inhibited germinal vesicle breakdown (GVBD). This effect was shown to be dependent upon bright indirect light, since the drug was much less effective at GVBD inhibition under conditions of very low illumination. Higher concentrations of chlorpromazine and W-7 (100 microM) inhibited GVBD and activated eggs with intact germinal vesicles as determined by fertilization envelope formation and the onset of ameboid activity. Neither egg activation nor inhibition of calmodulin stimulation of phosphodiesterase activity in vitro was affected by light. These results are consistent with a role for calmodulin in egg activation and GVBD, but suggest that chlorpromazine in bright light may prevent GVBD by some mechanism other than calmodulin inhibition.     

Studies on the appearance and nature of a maturation-inducing factor in the cytoplasm of amphibian oocytes exposed to progesterone

Full-grown oocytes of amphibians respond in vitro to exogenous progesterone by undergoing physiological maturation (breakdown of the germinal vesicle (GVBD), meiosis, and acquisition of the capacity for activation). Both cytoplasm and “cytosol” from maturing oocytes have been shown to produce similar events when injected into unstimulated oocytes. This activity appeared within 4 hr after hormone treatment in Rana pipiens and Xenopus laevis and represents the earliest detectable, specific response of the oocyte yet observed, i.e., 6–8 hr before GVBD in Rana. Maturing oocytes retained activity as long as 100 hr after exposure to progesterone, and activity was also obtained from ovulated eggs and cleaving embryos. In addition, cytoplasm from Rana pipiens, Xenopus laevis, or Ambystoma mexicanum was effective in inducing maturation in oocytes of each other, indicating a lack of specificity.Recipient oocytes of Xenopus laevis consistently began to mature within 1.5–3 hr after injection of maturing cytoplasm, well before progesterone-treated controls. The timing of the response was closely related to the quantity of cytoplasm transferred, suggesting the presence of both a minimum and threshold level of cytoplasmic factor. Serial cytoplasmic transfer in Xenopus oocytes showed no significant loss of activity through 10 injections.     

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.     

Development of pronuclei from human spermatozoa injected microsurgically into frog (Xenopus) eggs

Human spermatozoa were demembranated with Triton X-100 (TX) and injected into the mature eggs of Xenopus laevis. The nuclei of these spermatozoa decondensed and developed into pronuclei. Chromosomes did not appear in the eggs until the end of a 5-hr incubation period. When the demembranated human spermatozoa were further treated with dithiothreitol (DTT) before they were injected into the eggs, the sperm nuclear decondensation and pronuclear development took place considerably faster than in spermatozoa treated with the detergent alone. By the end of the 5-hr incubation period, decondensed chromatin threads or chromosome-like structures appeared, but none of the eggs cleaved. When human spermatozoa were injected into full-grown ovarian oocytes with intact germinal vesicle (GV) or oocytes which had matured without GV, the nuclei of a proportion of TX-treated and all TX-DTT-treated sperm decondensed but showed no sign of developing into pronuclei. Sperm nuclei injected into maturing oocytes formed condensed chromatin fragments as long as the oocytes were not activated, but they transformed into pronuclei when the oocytes were stimulated with electric shock. These results indicate that the cytoplasmic factors responsible for the decondensation of human sperm nuclei are present in egg cytoplasm independent of GV-materials. We also suggest that the factors controlling development of decondensed sperm nuclei into pronuclei are dependent on GV materials.     

Subcortical rotation in Xenopus eggs: an early step in embryonic axis specification

The amphibian egg undergoes a rotation of its subcortical cytoplasm relative to its surface during the first cell cycle. Nile blue spots applied to the egg periphery move with the subcortical cytoplasm and make rotation directly observable (J.-P. Vincent, G.F. Oster, and J. C. Gerhart (1986). Dev. Biol. 113, 484). We have previously shown that the direction of rotation accurately predicts the orientation of the embryonic axis developed by the egg. This suggests an important role for subcortical rotation in axis specification. In this report, we provide two kinds of experimental evidence for the essential role of rotation, and against a role for other concurrent cytoplasmic movements such as the convergence of subcortical cytoplasm toward the sperm entry point in the animal hemisphere. First, dispermic eggs develop only one embryonic axis, which is oriented accurately in line with the direction of the single rotation movement and not with the two convergence foci that form in the animal hemisphere. Rotation probably modifies the vegetal, not animal, hemisphere since axial development is normal in dispermic eggs despite highly altered animal subcortical movement. Second, we show that the amount of rotation correlates with the extent of dorsal development. UV irradiation of the vegetal hemisphere, or cold shock of the egg, inhibits rotation effectively. When there is no rotation, there is no dorsal development. On average within the egg population, increasing amounts of rotation correlate with the increasingly anterior limit of the dorsal structures of the embryonic body axis. However, individual partially inhibited eggs vary greatly in the amount of axis formed following a given amount of movement. Furthermore, the egg normally rotates more than is necessary for the development of a complete axis. These findings suggest that rotation, although essential, does not directly pattern the antero-posterior dimension of the body axis, but triggers a response system which varies from egg to egg in its sensitivity to rotation. This system is artificially sensitized by exposure of the egg to D2O shortly before rotation. We show that D2O-treated eggs produce extensive axes despite very limited rotation, often developing into hyperdorsal embryos. However, like normal eggs, they depend on rotation and cannot form dorsal structures if it is eliminated.     

Chromosome condensation in pig oocytes: lack of a requirement for either cdc2 kinase or MAP kinase activity

In this study, butyrolactone I (BL I), a potent and specific inhibitor of cyclin-dependent kinases (cdk), is shown to inhibit germinal vesicle breakdown (GVBD) in pig oocytes. Oocytes treated with 100 microM BL I were arrested in the germinal vesicle (GV)-stage and displayed low activity of cdc2 kinase and MAP kinase. Nevertheless, chromosome condensation occurred and highly condensed bivalents were seen within an intact GV after a 24-hr culture in the presence of BL I. The inhibitory effect of BL I on MAP kinase activation during culture was likely mediated through a cdk-dependent pathway, since MAP kinase activity present in extracts derived from metaphase II eggs was not inhibited by BL I. The block of GVBD could be released by treating oocytes with okadaic acid (OA), an inhibitor of type 1 and 2A phosphatases; 82% of the oocytes treated with the combination of OA/BL I underwent GVBD, and MAP kinase became activated, while cdc2 kinase remained inhibited. These results suggest that both chromosome condensation and GVBD could occur without activation of cdc2 kinase, whereas an increase in MAP kinase activity may be a requisite for GVBD in pig oocytes in conditions when cdc2 kinase activation is blocked by BL I.     

Cytoplasmic Maturity Revealed by the Structural Changes in Incorporated Spermatozoon during the Course of Starfish Oocyte Maturation

Immature oocytes of the starfish, Asterina pectinifera, are polyspermic. Spermatozoa can enter immature oocytes upon insemination, but the changes associated with the fertilization process in oocytes matured with 1-methyladenine (1-MeAde), such as the formation of aster and pronucleus, were not observed. After immature oocytes, previously inseminated, were matured with 1-MeAde, the formation of the sperm monaster was observed during germinal vesicle breakdown (GVBD). Amphiasters and pronuclei were formed after the formation of the second polar body. The acquisition by oocytes of the capacity to undergo the normal process of fertilization, therefore, occurs during the course of oocyte maturation. After injection of the cytoplasm of maturing oocytes into inseminated immature oocytes, the formation of aster and pronucleus was observed, suggesting that maturation-promoting factor (MPF) may be involved in establishing the cytoplasmic conditions (cytoplasmic maturity) necessary for the fertilization process to occur. In contrast, when enucleated, inseminated halves of immature oocytes were treated with 1-MeAde, only monasters were formed, while in the nucleated halves both amphiasters and sperm pronuclei were formed. Thus, germinal vesicle material is required for the formation of amphiaster and sperm pronucleus but not for the formation of monaster. It is possible that the amount of MPF produced in enucleated halves was sufficient only for the formation of the monaster but not for the formation of the amphiaster and pronucleus, since it has been previously established that germinal vesicle material is necessary for the amplification of MPF. The formation of the monaster in the enucleated halves at a time corresponding to GVBD in nucleated controls suggests that the amount of MPF needed for this event is rather small. For the induction of subsequent fertilization process, large amounts of MPF may be required to establish the necessary cytoplasmic conditions, although other possible role of nuclear material is not excluded.     

Mouse-rabbit germinal vesicle transfer reveals that factors regulating oocyte meiotic progression are not species-specific in mammals

A series of experiments were designed to evaluate the meiotic competence of mouse oocyte germinal vesicle (GV) in rabbit ooplasm. In experiment 1, an isolated mouse GV was transferred into rabbit GV-stage cytoplast by electrofusion. It was shown that 71.8% and 63.3% of the reconstructed oocytes completed the first meiosis as indicated by the first polar body (PB1) emission when cultured in M199 and M199 + PMSG, respectively. Chromosomal analysis showed that 75% of matured oocytes contained the normal 20 mouse chromosomes. When mouse spermatozoa were microinjected into the cytoplasm of oocytes matured in M199 + PMSG and M199, as many as 59.4% and 48% finished the second meiosis as revealed by the second polar body (PB2) emission and a few fertilized eggs developed to the eight-cell stage. In experiment 2, a mouse GV was transferred into rabbit MII-stage cytoplast. Only 13.0-14.3% of the reconstructed oocytes underwent germinal vesicle breakdown (GVBD) and none proceeded past the MI stage. When two mouse GVs were transferred into an enucleated rabbit oocyte, only 8.7% went through GVBD. In experiment 3, a whole zona-free mouse GV oocyte was fused with a rabbit MII cytoplast. The GVBD rates were increased to 51.2% and 49.4% when cultured in M199 + PMSG and M199, respectively, but none reached the MII stage. In experiment 4, a mouse GV was transferred into a partial cytoplasm-removed rabbit MII oocyte in which the second meiotic apparatus was still present. GVBD occurred in nearly all the reconstructed oocytes when one or two GVs were transferred and two or three metaphase plates were observed in ooplasm after culturing in M199 + PMSG for 8 hr. These data suggest that cytoplasmic factors regulating the progression of the first and the second meioses are not species-specific in mammalian oocytes and that these factors are located in the meiotic apparatus and/or its surrounding cytoplasm at MII stage.     

Changes in protein phosphorylation accompanying maturation of Xenopus laevis oocytes

Protein phosphorylation has been measured after injection of [³²P]phosphate into oocytes of Xenopus laevis undergoing progesterone-induced meiotic maturation. As oocytes mature, there is a burst of nonyolk protein phosphorylation several hours after progesterone exposure and shortly before germinal vesicle breakdown (GVBD). This burst is not due to changes in the specific activity of the phosphate or ATP pool. Enucleated oocytes exposed to progesterone also experience the burst, indicating the cytoplasmic location of phosphoprotein formation. When an oocyte receives an injection of cytoplasm containing the maturation-promoting factor (MPF), a burst of protein phosphorylation occurs immediately, and GVBD occurs shortly thereafter, even in the presence of cycloheximide. Under a variety of conditions promoting or blocking maturation, oocytes which undergo GVBD are the only ones to have experienced the phosphorylation burst. The results suggest that the protein phosphorylation burst is a necessary step in the mechanism by which MPF promotes GVBD.     

Activity of maturation promoting factor in mammalian oocytes after its dilution by single and multiple fusions

Mouse and porcine fully grown oocytes at metaphase I(MI) were fused to one or more fully grown oocytes of the same species that contained an intact germinal vesicle (GV). In fused cells containing one GV, premature chromosome condensation (PCC) was observed. In fused cells containing more than one GV, germinal vesicle breakdown (GVBD) and PCC were delayed. Fusion of an MI fully grown oocyte with a growing oocyte resulted in rapid PCC, whereas, fusion of an MI fully grown oocyte with more than one growing oocyte resulted in neither PCC nor GVBD. Moreover, MI chromosomes formed a clump of chromatin. Results of these experiments suggest that the delay in GVBD in fusions of MI oocytes with multiple GV-intact oocytes was due to dilution of maturation promoting factor (MPF) by the cytoplasm of the GV-intact oocytes and that the cytoplasm of growing oocytes can inhibit MPF present in MI oocytes.     

Effect of cycloheximide upon maturation of bovine oocytes

Germinal vesicle breakdown (GVBD) of bovine oocytes was completely blocked by cycloheximide added to culture medium at concentrations of 1-20 micrograms/ml. Nevertheless, under such conditions a certain degree of chromatin condensation inside the germinal vesicle was observed. The inhibitory effect was not influenced by the presence or absence of cumulus cells and was fully reversible; but the process of GVBD was then significantly accelerated. The critical period in which the proteins necessary for GVBD are synthesized lasts approximately the first 5 h of culture. When germinal vesicle-arrested oocytes are fused to maturing bovine oocytes containing condensed chromosomes, GVBD of immature oocytes occurs within 3 h, even in the presence of cycloheximide. In the mouse, GVBD cannot be inhibited by protein synthesis inhibitors. When immature mouse oocytes are fused with immature bovine oocytes and the giant cells are then cultured in cycloheximide-supplemented medium, both GVs are observed, or only mouse GVBD occurs in common cytoplasm after 8 h of culture. We conclude that protein synthesis is necessary for GVBD of bovine oocytes. Our results also suggest that maturation-promoting factor (MPF) is not autocatalytically amplified in mammalian oocytes.     

小鼠卵母细胞体外成熟不同阶段对钙的依赖性

To determine the role of calcium and calmodulin in mouse oocyte maturation, we examined the distribution of intracellular calcium during mouse oocyte maturation by using Mira Cal Imaging System. The calcium was present homogeneously in oocytes with intact germinal vesicle (GV) and accumulated around the nuclear region after GV breakdown(GVBD). The high level of calcium disappeared 6 hours later after GVBD. In the presence of 50 mumol/L BAPTA/AM, we failed to observe this phenomena. All eggs treated with 20 mumol/L W7, an antagonist of calmodulin, 50 mumol/L BAPTA/AM, a calcium chelator, could not develop to metaphase II (MII), although GVBD was not affected. We also detected the activity of a cytoplasmic maturation-promoting factor (MPF). W7 and BAPTA/AM had no effects on the rise of MPF activity in the course of maturation. We suggest that compartment distribution of calcium around nuclear region plays an important role in mouse oocyte maturation.