Protein phosphorylation and oocyte maturation. I. Induction of starfish oocyte maturation by intracellular microinjection of a phosphatase inhibitor, alpha-naphthylphosphate

Oocyte maturation (meiosis re-initiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Following hormonal stimulation of the oocyte, an intracellular Maturation Promoting Factor (MPF) appears in the cytoplasm which triggers nuclear envelope breakdown and maturation divisions. alpha-Naphthylphosphate (alpha-NP), a widely used phosphatase inhibitor/substrate, was found to induce oocyte maturation when microinjected intracellularly (50% maturation of 3.5 mM; 100% above 6mM, final intracellular concentration) into oocytes of Marthasterias and Asterias but not of Astropecten. As 1-MeAde, alpha-NP triggers a complete maturation, i.e. germinal vesicle breakdown, extrusion of the two polar bodies and formation of the female pronucleus. The kinetics of alpha-NP-induced maturation (35-45 min) is, however, longer than the kinetics of 1-MeAde-induced maturation (18-20 min). The addition of alpha-NP externally to oocytes does not trigger maturation. Among several reported phosphatase inhibitors, including two natural protein phosphatase inhibitors and several products structurally related to alpha-NP, only alpha-NP was found capable of inducing maturation when microinjection into oocytes. alpha-NP triggers the appearance of MPF activity in the cytoplasm of oocytes into which it has been injected. Although alpha-NP-induced maturation is insensitive to inhibitors whose action is known to be restricted to the hormone-dependent period (such as the protease inhibitor leupeptin), it is blocked by inhibitors of MPF action (such as nicotinamide and lithium). Finally it was found that alpha-NP-induced maturation is inhibited by simultaneous microinjection of protein phosphatase-2A; also, alpha-NP, classically used as an inhibitor of acid and alkaline phosphatases, is able to inhibit protein phosphatases, is able to inhibit protein phosphatases 1 and 2 A. The addition of alpha-NP to oocytes increases the level of phosphorylated proteins. These results constitute direct evidence that an elevated level of phosphorylated proteins is sufficient to trigger MPF activity and to induce maturation.     

Inhibition of Starfish Oocyte Maturation by Tumor-Promoting Phorbol Esters*

Effect of tumor promoters including phorbol esters and teleocidin on 1-methyladenine (1-MeAde)-induced oocyte maturation was studied in the starfish. When isolated immature oocytes were treated with 1-MeAde and 12-O-tetradecanoylphorbol-13-acetate (TPA), 1-MeAde-induced maturation was completely inhibited at more than 2.5 μg/ml. However, if TPA was added after the hormone-dependent period (the minimum period wherein 1-MeAde is required), such maturation-inhibiting effect was no longer observed. Pretreatment with TPA for 5 min showed that its inhibitory action is irreversible. However, when TPA-injected oocytes were treated with 1-MeAde, all oocytes underwent germinal vesicle breakdown (GVBD). GVBD was induced in TPA-treated oocytes upon injection of the cytoplasm of maturing oocytes containing maturation-promoting factor (MPF). These facts show that TPA acts on the oocyte surface to inhibit the production of MPF. Retinoids including retinal, retinol and retinoic acid reversed the inhibitory effect of TPA on 1-MeAde-induced maturation. Experiments with various phorbol esters showed a good correlation between their maturation-inhibiting activity and their known tumor-promoting activity. Further, telecoidin, which is structurally unrelated to phorbol esters, inhibited 1-MeAde action. Since both tumor-promoting phorbol esters and teleocidin are known to activate Ca²⁺ -activated, phospholipid-dependent protein kinase (protein kinase C) and their activation effect is inhibited by retinoids, it appears that the activation of protein kinase C by tumor promoters is involved in blocking of 1-MeAde action.     

Role of germinal vesicle material in producing maturation-promoting factor in starfish oocyte

In starfish, oocyte maturation is induced by 1-methyladenine (1-MeAde). 1-MeAde acts on the oocyte surface to produce a cytoplasmic maturation-promoting factor (MPF), which in turn brings about germinal vesicle breakdown and subsequent process of oocyte maturation. The participation of germinal vesicle material in the production of MPF was investigated with oocytes of the starfish, Asterina pectinifera. When enucleated oocytes or oocyte fragments without germinal vesicles were treated with 1-MeAde, MPF was found to be produced. However, the amount of MPF produced was small as compared with that in the case of intact oocytes with germinal vesicles. The capacity of the enucleated oocytes to produce MPF was restored when germinal vesicle material was injected. On the other hand, it has been known that the amount of MPF increases when MPF is injected into intact oocytes (amplification of MPF). However, in the case of enucleated oocytes such increase of MPF was no longer observed, suggesting that germinal vesicle material is required for MPF amplification.     

Protein phosphorylation and oocyte maturation : I. Induction of starfish oocyte maturation by intracellular microinjection of a phosphatase inhibitor, α-naphthylphosphate

Oocyte maturation (meiosis re-initiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Following hormonal stimulation of the oocyte, an intracellular Maturation Promoting Factor (MPF) appears in the cytoplasm which triggers nuclear envelope breakdown and maturation divisions. α-Naphthylphosphate (α-NP), a widely used phosphatase inhibitor/substrate, was found to induce oocyte maturation when microinjected intracellularly (50% maturation at 3.5 mM; 100% above 6 mM, final intracellular concentration) into oocytes of Marthasterias and Asterias but not of Astropecten. As 1-MeAde, α-NP triggers a complete maturation, i.e. germinal vesicle breakdown, extrusion of the two polar bodies and formation of the female pronucleus. The kinetics of α-NP-induced maturation (35–45 min) is, however, longer than the kinetics of 1-MeAde-induced maturation (18–20 min). The addition of α-NP externally to oocytes does not trigger maturation. Among several reported phosphatase inhibitors, including two natural protein phosphatase inhibitors and several products structurally related to α-NP, only α-NP was found capable of inducing maturation when microinjected into oocytes. α-NP triggers the appearance of MPF activity in the cytoplasm of oocytes into which it has been injected. Although α-NP-induced maturation is insensitive to inhibitors whose action is known to be restricted to the hormone-dependent period (such as the protease inhibitor leupeptin), it is blocked by inhibitors of MPF action (such as nicotinamide and lithium). Finally it was found that α-NP-induced maturation is inhibited by simultaneous microinjection of protein phosphatase-2A; also, α-NP, classically used as an inhibitor of acid and alkaline phosphatases, is able to inhibit protein phosphatases 1 and 2 A. The addition of α-NP to oocytes increases the level of phosphorylated proteins. These results constitute direct evidence that an elevated level of phosphorylated proteins is sufficient to trigger MPF activity and to induce maturation.     

Breakdown of starfish ovarian follicle induced by maturation-promoting factor

Immature starfish oocytes are surrounded by envelopes consisting of follicular cells. These cells adhere to each other and to the oocyte, immobilizing the latter within the ovary. When isolated oocytes in their follicles are treated with 1-methyladenine (1-MeAde), germinal vesicle breakdown (GVBD) and follicular envelope breakdown (FEBD) occur simultaneously. The 1-MeAde acts on the oocyte surface to produce a maturation-promoting factor (MPF) in the cytoplasm, which brings about GVBD. In the present study, MPF was found to induce FEBD as well as GVBD when injected into immature oocytes with their follicles in Asterina pectinifera. Although GVBD was induced by MPF in the presence of cytochalasin D, this drug prevented MPF-induced FEBD, and each follicular cell remained in situ on the surface of the oocyte. However, desmosomes connecting the processes of the follicle cell with the oocyte surface were disrupted following MPF injection even in the presence of cytochalasin D, and the processes became detached from the oocyte. FEBD occurred in these oocytes when cytochalasin D was removed, resulting in the formation of a small follicular clump by microfilament-mediated contraction of the follicle cells. These results show that FEBD is not brought about by the direct action of 1-MeAde but by the action of MPF. Therefore, in starfish, spawning as well as oocyte maturation is directly triggered by MPF produced under the influence of 1-MeAde.     

Protein phosphorylation and oocyte maturation : II. Inhibition of starfish oocyte maturation by intracellular microinjection of protein phosphatases 1 and 2A and alkaline phosphatase

Oocyte maturation (meiosis re-initiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Following hormonal stimulation of the oocyte, an intracellular Maturation Promoting Factor (MPF) appears in the cytoplasm which triggers nuclear envelope breakdown and maturation divisions. Microinjection of pure preparations of the catalytic subunits of protein phosphatases 1 and 2A inhibits 1-MeAde-induced maturation in a dose-dependent manner. Calmodulin-dependent protein phosphatase 2B is inefficient. Maturation induced by mimetics of 1-MeAde, such as dithiothreitol (DTT), methylglyoxal-bis(guanylhydrazone) (MGBG), 8-hydroxyeicosatetraenoic acid (8 HETE) and arachidonic acid (AA) is also inhibited by these protein phosphatases. In all cases inhibition can be reversed by increasing the concentration of 1-Me-Ade or of mimetic. Alkaline phosphatase also inhibits maturation in a dose-dependent way and in a reversible manner. Microinjection of protein phosphatase is still effective when preformed long after the end of the hormone-dependent period, and can even be effective a few minutes before the breakdown of the nuclear envelope. No detectable MPF activity is found in 1-MeAde-treated phosphatase-injected oocytes. However, microinjection of phosphatase 2A simultaneously with MPF (obtained from 1-MeAde-treated donors) does not result in inhibition. These results constitute direct evidence for the necessity of an elevated level of phosphorylated proteins for MPF activity and maturation. The mode of action of 1-MeAde in inducing starfish oocyte maturation is discussed in relation to protein phosphorylation.     

INDUCTION OF OOCYTE MATURATION BY DISULFIDE-REDUCING AGENT IN THE SEA CUCUMBER, STICHOPUS JAPONICUS

1-Methyladenine (1-MeAde) is known to be a natural inducer of starfish oocyte maturation. Disulfide-reducing agents such as dithiothreitol (DTT) and 2, 3-dimercapto-1-propanol (BAL) are known to mimic the action of 1-MeAde in inducing starfish oocyte maturation. Although 1-MeAde failed to induce oocyte maturation in sea cucumbers, breakdown of germinal vesicles and subsequent meiotic behaviour of chromosomes were induced by the treatment with DTT in the pronase-treated oocytes of the sea cucumber, Stichopus japonicus. These findings suggest that reduction of disulfide bonds plays an important role in triggering oocyte maturation in some marine forms such as echinoderms.     

Extraction and preliminary characterization of maturation-promoting factor from starfish oocytes

Cytoplasm of maturing starfish oocytes possesses a factor which induces maturation upon injection into immature oocytes. Such maturation-promoting factor (MPF) was extracted from maturing oocytes of Asterina pectinifera and characterized preliminarily. After 1-methyladenine (1-MeAde) treatment, maturing oocytes were packed in a centrifuge tube to remove jelly and excess medium, and then crushed by centrifugation. The turbid supernatant was homogenized with a buffer containing NaF, Na-beta-glycerophosphate, ATP, EGTA and leupeptin, followed by centrifugation. MPF extracted in the supernatant was purified partially by ammonium sulfate precipitation, hydrophobic chromatography on pentyl-agarose and gel filtration on Sephacryl S-300. The final material induced maturation in the recipient starfish oocytes when 0.5 ng of protein was injected in a volume of 400 pl. The maturation response included germinal vesicle breakdown, and formation of polar bodies and egg pronucleus. Such MPF preparation induced maturation in oocytes of Xenopus laevis as well. Further, starfish MPF was found to be a heat-labile protein; its molecular weight (MW) was estimated as 300 X 10(3) D by gel filtration and its sedimentation coefficient value as 5S by centrifugation on sucrose density gradients.     

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.     

Possible MIS Production by Follicle Cells in Spontaneous Oocyte Maturation of the Ascidian, Halocynthia roretzi

Outer and inner follicle cell-enclosed oocytes (oocyte complexes) of Halocynthia roretzi underwent germinal vesicle breakdown (GVBD) within 2 hr when transferred from ovaries to normal seawater of pH 8 (NSW). Extrusion of test cells (TC) into the perivitelline space and elevation of the chorion also occurred. This phenomenon was designated as spontaneous oocyte maturation.
Seawater of low pH, protease inhibitors such as leupeptin or soybean trypsin inhibitor (SBTI), and calcium deficiency inhibited the spontaneous maturation only when introduced to the NSW during the first 10 minutes of incubation. GVBD-blocked complexes underwent GVBD after addition of trypsin regardless of pH or the absence of calcium ions. The oocytes from which follicle cells were removed with glycosidase did not undergo GVBD in NSW, but addition of trypsin triggered GVBD in these defolliculated oocytes (TC oocytes). Furthermore, incubation media in which spontaneous maturation had occurred, induced GVBD in the TC oocytes. This GVBD-inducing activity was heat-labile and was inhibited by leupeptin.
These results indicate that in the first step of the spontaneous oocyte maturation, outer and/or inner follicle cells give a signal to the oocyte itself or TC oocyte. This signal is likely to be trypsin-like.     

Arachidonic acid, 12- and 15-hydroxyeicosatetraenoic acids, eicosapentaenoic acid, and phospholipase A2 induce starfish oocyte maturation

In starfish oocyte maturation (meiosis reinitiation) is induced by the natural hormone 1-methyladenine (1-Me-Ade). This paper shows that arachidonic acid (AA) induces oocyte maturation at concentrations above 0.5 microM. This maturation shares many characteristics with 1-MeAde-induced maturation: same kinetics, same required contact time, same stimulations of protein phosphorylation and sodium influx. Although calcium facilitates the AA-induced but not the 1-MeAde-induced maturation, AA, like 1-MeAde, does not stimulate the uptake of calcium. Calcium does not facilitate the uptake of AA by oocytes. Out of 36 different fatty acids (saturated and unsaturated), only eicosatetraenoic (AA) and eicosapentaenoic acids were found to mimic 1-MeAde. Calcium-dependent phospholipases A2 from bee venom and Naja venom also induce maturation (0.1-1 unit/ml) when added externally to the oocytes. Phospholipase A2 inhibitors (quinacrine, bromophenacylbromide) block maturation; inhibition is reversed by increasing the 1-MeAde concentration and only occurs during the hormone-dependent period. AA is usually metabolized through oxidation by cyclooxygenase or lipoxygenase. Cyclooxygenase inhibitors (acetylsalicylic acid, indomethacin, tolazoline) do not block maturation; prostaglandins E2, D2, F2 alpha, I2, and thromboxane B2 do not induce meiosis reinitiation. On the other hand, lipoxygenase inhibitors (quercetin, butylated hydroxytoluene, and eicosatetraynoic acid) block 1-MeAde-induced maturation; although leukotrienes (A4, B4, C4, D4, E4) have no effects on oocytes, two other lipoxygenase products, 12- and 15-hydroxyeicosatetraenoic acids (and their corresponding hydroperoxy-) induce oocyte maturation (around 1 microM). The possible mode of action of the fatty acids inducing oocyte maturation is discussed.     

INHIBITION OF GERMINAL VESICLE BREAKDOWN AND POLAR BODY FORMATION BY NICOTINAMIDE IN STARFISH AND SURF CLAM OOCYTES*

Nicotinamide inhibited both germinal vesicle breakdown (GVBD) and polar body formation (PBF) in surf clam and starfish oocytes. In the surf clam nicotinamide at 0.3 mM completely blocked PBF in the fertilized oocytes. For blockage of GVBD higher concentration was required. In the starfish, nicotinamide (30 mM) prevented PBF but not GVBD, when added 7 min after the commencement of 1-methyladenine (1-MeAde) administration. These results suggest that PBF is blocked by nicotinamide independent of its effect on GVBD. In the case of starfish, NAD⁺was more effective than nicotinamide in inhibiting oocyte maturation. Nicotinamide also blocked GVBD induced by microinjection of the cytoplasm containing maturation-promoting factor (MPF) obtained from 1-MeAde-treatcd oocytes. These results suggest that nicotinamide prevents the action of MPF rather than inhibiting the interaction of 1-McAde with cell membrane or the induction of MPF.     

Intracellular microinjection of alkaline buffers reversibly inhibits the initial phase of hormone action in meiosis reinitiation of starfish oocytes

Intracellular microinjection of alkaline Hepes-KOH buffers, which increases intracellular pH (pHI) from 6.92 to 7.70 in fully grown prophase-blocked oocytes of the starfish Marthasterias glacialis, like external application of ammonia and other weak bases (M. Doree, K. Sano, and H. Kanatani, 1982, Dev. Biol.90, 13–17), inhibited meiosis reinitiation induced by 1-methyladenine (1-MeAde) or dithiothreitol (DTT), a mimetic of the hormone. Oocytes could be released from inhibition by raising the concentration of hormone or of its mimetic. Increasing pHI to 7.70 neither inhibited nor delayed meiosis reinitiation when pH was clamped after the end of the hormone-dependent period, the period during which 1-MeAde is required in the external medium for meiosis to occur, whereas it blocked the action of the hormone at low concentration when performed before the end of the hormone-dependent period. When hormone concentration was higher, germinal vesicle breakdown (GVBD) occurred, but duration of the hormone-dependent period was increased. Delay introduced by alkalinization for oocytes to reach GVBD after 1-MeAde addition was smaller at high than at medium concentrations of the hormone. Increasing pHI did not inhibit action of MPF, the cytoplasmic maturation factor which induces GVBD and the subsequent process of meiotic maturation following hormonal treatment of prophase-blocked oocytes.     

Oocyte-surface factor responsible for 1-methyladenine-lnduced oocyte maturation in starfish

Fully grown oocytes of the starfish Asterina pectinifera, undergo breakdown of their germinal vesicles and subsequent maturation on treatment with 1-methyladenine (1-MeAde). However, oocytes treated with seawater containing 0.010% Triton X-100 lost the capacity to respond to 1-MeAde and their germinal vesicles remained intact. These decapacitated oocytes once again ac-quired the capacity to respond to l-Me Ade when they were incubated in sea water containing the extract of fully grown oocytes treated with Triton X-100, from which the Triton X-100 was removed after extraction by means of Bio-Beads SM-2 (TXE). Recovery of the capacity was also observed after washing such TXE-treated oocytes with sea water. These results suggest that some factor (probably 1-MeAde receptor or its fragment), extracted from the oocyte surface (plasma mem-brane) by nonionic detergent, was reconstituted on the oocyte surface so that the capacity of the oocytes to respond to 1-MeAde was recovered. The factor was heat-stable and resistant to treat-ment with proteolytic enzymes.     

Immobilized methylglyoxal-bis(guanylhydrazone) induces starfish oocyte maturation

Methylglyoxal-bis(guanylhydrazone) diHCl (MGBG), an inhibitor of S-adenosylmethionine decarboxylase, was found to induce starfish oocyte maturation at concentrations above 30 microM. Among several analogs of MGBG three induce oocyte maturation and one lacks the maturation-inducing activity while possessing the S-adenosylmethionine decarboxylase-inhibiting activity. Although MGBG is required during a slightly longer period than the natural hormone 1-methyladenine (1-MeAde), the maturation kinetics are identical. MGBG-induced maturation is sensitive to the same inhibitors as 1-MeAde-induced maturation (theophylline, caffeine, procaine, nicotine, NH4Cl, dansylcadaverine, vinblastine, R24571, and trifluoperazine). Inhibition is reversed by increasing the MGBG concentration. MGBG also induces an increase of protein phosphorylation. MGBG and 1-MeAde were separated on the basis of charcoal adsorption, MgSO4 precipitation, and thin-layer chromatography. MGBG covalently linked to CH-Sepharose 4B induces maturation in oocytes whose jelly layer and vitelline coat have been removed by a moderate pronase treatment, but not in the untreated oocytes. The MGBG-CH-Sepharose 4B beads come in close contact with the plasma membrane only in the pronase-treated oocytes. The mode of action of MGBG and the implications of these results in the purification of the 1-MeAde receptor are discussed.     

Starfish oocyte maturation: evidence for a cyclic AMP-dependent inhibitory pathway

Oocyte maturation (meiosis reinitiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Cyclic AMP seems to play a negative role in maturation since 1-MeAde triggers a decrease of the oocyte cAMP concentration and since intracellular microinjections of cAMP delay or inhibit maturation. Cyclic GMP is also inhibitory but other nucleotides such as cCMP, cIMP, and cUMP are inactive. The involvement of cAMP and cGMP in the control of oocyte maturation has been further investigated by the use of the stereoisomers of the phosphodiesterase-stable adenosine and guanosine 3',5'-phosphorothioates (cAMPS and cGMPS). The Sp isomers of cAMPS and cGMPS respectively activate cAMP-dependent protein kinase and cGMP-dependent kinase, while the Rp isomers inhibit the kinases. Extracellular addition of these cAMPS and cGMPS isomers has no effect on the oocytes. Intracellular microinjection of the kinase-activating (Sp)-cAMPS and (Sp)-cGMPS delays or inhibits 1-MeAde-induced maturation in a concentration-dependent manner (I50, 30 and 300 microM, respectively). Microinjections of (Rp)-cAMPS and (Rp)-cGMPS have no inhibitory effects and neither trigger nor facilitate maturation. Using various analogs, we found that the delaying or inhibiting effect is restricted to the compounds activating cAMP-dependent kinase, while the compounds inactive on or inhibiting the kinase have no effects on maturation. The inhibitory effect of (Sp)-cAMPS can be reversed by comicroinjection of the heat-stable inhibitor of cAMP-dependent protein kinase, by comicroinjection of the antagonist (Rp)-cAMPS, or by an increase in the 1-MeAde concentration. The negative effects of (Sp)-cAMPS or (Sp)-cGMPS are observed only when these isomers are microinjected during the hormone-dependent period. These results suggest that a cAMP-dependent inhibitory pathway participates in the maintenance of the prophase arrest of oocytes and that 1-MeAde acts both by inhibiting this negative pathway (dis-inhibitory pathway) and by stimulating a parallel activatory pathway leading to oocyte maturation. The generality of this mechanism is discussed.     

Several signaling pathways are involved in the control of cattle oocyte maturation

The main limit of in vitro production of domestic mammal embryos comes from the low capacity of in vitro matured oocytes to develop after fertilization. As soon as they are separated from follicular environment, oocytes spontaneously resume meiosis without completion of their terminal differentiation. Roscovitine (ROS), an inhibitor of M-phase promoting factor (MPF) kinase activity reversibly blocks the meiotic resumption in vitro. However, in cattle maturing oocytes several cellular events such as protein synthesis and phosphorylation, chromatin condensation and nuclear envelope folding escape ROS inhibition suggesting the alternative pathways in oocyte maturation. We compared the level of synthesis and phosphorylation of several protein kinases during bovine cumulus oocyte complex (COC) maturation in vitro in the presence or not of epidermal growth factor (EGF) and ROS. We showed that during the EGF-stimulated maturation, ROS neither affected the decrease of EGF receptor (EGFR) nor did inhibit totally its phosphorylation in cumulus cells and also did not totally eliminate tyrosine phosphorylation in oocytes. However, ROS did inhibit the Phosphoinositide 3-kinase (PI3) activity when oocytes mature without EGF. Accumulation of Akt/PKB (protein kinase B), JNK1/2 (jun N-terminal kinases) and Aurora-A in oocytes during maturation was not affected by ROS. However, the phosphorylation of Akt but not JNKs was diminished in ROS-treated oocytes. Thus, PI3 kinase/Akt, JNK1/2 and Aurora-A are likely to be involved in the regulation of bovine oocyte maturation and some of these pathways seem to be independent to MPF activity and meiotic resumption. This complex regulation may explain the partial meiotic arrest of ROS-treated oocytes and the accelerated maturation observed after such treatment.     

Function of the Mos/MAPK pathway during oocyte maturation in the Japanese brown frog Rana japonica

Fully grown immature oocytes acquire the ability to be fertilized with sperm after meiotic maturation, which is finally accomplished by the formation and activation of the maturation-promoting factor (MPF). MPF is the complex of Cdc2 and cyclin B, and its function in promoting metaphase is common among species. The Mos/mitogen-activated protein kinase (MAPK) pathway is also commonly activated during vertebrate oocyte maturation, but its function seems to be different among species. We investigated the function of the Mos/MAPK pathway during oocyte maturation of the frog Rana japonica. Although MAPK was activated in accordance with MPF activation during oocyte maturation, MPF activation and germinal vesicle breakdown (GVBD) was not initiated when the Mos/MAPK pathway was activated in immature oocytes by the injection of c-mos mRNA. Inhibition of Mos synthesis by c-mos antisense RNA and inactivation of MAPK by CL100 phosphatase did not prevent progesterone-induced MPF activation and GVBD. However, continuous MAPK activation and MAPK inhibition through oocyte maturation accelerated and delayed MPF activation, respectively. Furthermore, Mos induced a low level of cyclin B protein synthesis in immature oocytes without the aid of MAPK. These results suggest that the general function of the Mos/MAPK pathway, which is not essential for MPF activation and GVBD in Rana oocytes, is to enhance cyclin B translation by Mos itself and to stabilize cyclin B protein by MAPK during oocyte maturation.     

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.