Hormone-induced cortical maturation ensures the slow block to polyspermy and does not couple with meiotic maturation in starfish

Meiotic progression in starfish oocytes is reinitiated by a maturation-inducing hormone called 1-methyladenine (1-MeAde). In addition to meiotic maturation, 1-MeAde induces cortical maturation in which cortical granules become competent to discharge in response to fusion of a single sperm, which results in the formation of the fertilization envelope. We found that subthreshold concentrations of 1-MeAde induce cortical maturation without germinal vesicle breakdown (GVBD). During cortical maturation, the IP3 sensitivity of calcium stores was increased as well as during meiotic maturation. When oocytes were exposed with 1-MeAde only on a hemisphere of oocytes, the IP3 sensitivity of the cortical region was increased only in the exposed hemisphere, suggesting that signals and components involved in cortical maturation do not readily spread in the cytoplasm. Although a specific inhibitor of phosphatidylinositol-3 kinase, LY294002 blocked both GVBD and cortical maturation, a Cdc2 kinase inhibitor, roscovitine did not block cortical maturation. Inhibition of Akt activation by injecting the competitors for Akt phosphorylation and membrane recruitment also blocked cortical maturation. These results suggest that the signaling pathway leading to Akt activation is common in cortical maturation and meiotic maturation, and Cdc2 activation was not required for cortical maturation.     

EFFECT OF LOCAL APPLICATION OF 1-METHYLADENINE ON THE SITE OF POLAR BODY FORMATION IN STARFISH OOCYTE*

Mechanism by which the site of polar body formation is determined in starfish oocytes was investigated in relation to the action of 1-methyladenine (1-MeAde). Local staining with Nile Blue of Asterina pectinifera oocytes revealed that there exists a prospective site of polar body formation (PSPBF) on the nearest surface to the position of germinal vesicle. The site of polar body formation was found to shift to some extent from PSPBF toward the area locally applied with 1-MeAde, suggesting that the actual site of polar body formation is not determined yet at the germinal vesicle stage. Oocytes whose germinal vesicles had been shifted by centrifugation from PSPBF to the opposite surface before the commencement of germinal vesicle breakdown (GVBD) (less than 15 min after 1-MeAde treatment), failed to form polar bodies, whereas oocytes centrifuged after commencement of GVBD (20 min after 1-MeAde treatment) did form polar bodies where their fading germinal vesicles had reached by centrifugation. In the oocytes which failed to form polar bodies by centrifugation, an aster was observed near PSPBF of each oocyte. When inseminated, every oocyte treated with 1-MeAde developed normally irrespectively of the mode of polar body formation including the site and the occurrence, and the animal pole of every larva was derived from PSPBF.     

Activation at the germinal vesicle stage of starfish oocytes produces parthenogenetic development through the failure of polar body extrusion

Starfish oocytes can be fertilized after germinal vesicle breakdown (GVBD) and artificial parthenogenesis can be induced by activating the oocytes after GVBD (post-GVBD activation). In the present study, parthenogenotes were obtained by the activation of immature oocytes with caffeine before treatment with 1-methyladenine (1-MeAde) to induce oocyte maturation. Most of the caffeine-treated eggs developed as tetraploids, as parthenogenotes produced by the post-GVBD activation. The parthenogenotes were derived only from eggs that failed to extrude polar bodies, mostly from eggs failing to extrude a second polar body. Eggs derived from immature oocytes activated by A23187, treated with 1-MeAde and post-treated with cytochalasin B failed to extrude polar bodies, and eventually developed into parthenogenetic embryos. These results indicate that the present parthenogenesis mechanism shares the same characteristics as that achieved by post-GVBD activation in the suppression of polar body formation as a key means for successful starfish parthenogenesis.     

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.     

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.     

6－Dimethylaminopurine（6－DMAP） Spontaneously Induces Interphase Transition Of Metaphase Mouse Oocytes

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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.     

Activation of maturation promoting factor and 26S proteasome assembly accelerated by a high concentration of 1-methyladenine in starfish oocytes

In the oocyte maturation process of the starfish Asterina pectinifera, the extent of inhibition of germinal vesicle breakdown (GVBD) by the proteasome inhibitor MG115 (benzyloxycarbonyl-leucyl-leucyl-norvalinal), as well as the timing of activation of pre-MPF (inactive maturation promoting factor) and 26S proteasome assembly, were found to be dependent on the concentration of the maturation-inducing hormone 1-methyladenine (1-MeAde). Activation of pre-MPF was accelerated by increasing the concentration of 1-MeAde, while there was little effect on the time required for GVBD. Assembly of the 26S proteasome was also accelerated by increasing the concentration of 1-MeAde. These results indicate that a higher concentration of 1-MeAde triggers acceleration of the assembly and increase in the activity of the 26S proteasome, which results in activation of pre-MPF, although there is little effect on the timing of GVBD. It was also clarified that the timing of GVBD is controlled by a rate-liming step after MPF-activation.     

Calcium- and Cyclic AMP-independent,Labile Protein Kinase Appearing during Starfish Oocyte Maturation: its Extraction and Partial Characterization*

A burst of protein phosphorylation and an appearance of maturation-promoting factor have been reported to occur shortly before germinal vesicle (nucleus) breakdown (GVBD) in 1-methyladenine-induced oocyte maturation of starfish. To detect if a protein kinase is activated before GVBD, protein kinase activity was compared in maturing oocytes which were just undergoing GVBD and immature oocytes of Asterina pectinifera. The oocytes were homogenized in a buffer modified from that used for extracting amphibian maturation-promoting factor. When the supernatant protein of homogenized immature oocytes was used as a substrate, protein kinase activity in the supernatant of the maturing oocytes was 7-fold higher than that of immature oocytes. The protein kinase in the supernatant of the maturing oocytes showed a high substrate specificity for histone H1 among the exogenous substrates examined, and the activity of the maturing oocytes for histone H1 was 6- to 7-fold higher than that of immature oocytes. The protein kinase detected in the maturing oocytes was very labile and was inhibited neither by ethylene glycol bis(β-aminoethyl ether)N, N, N′, N′-tetraacetic acid nor by the heat-stable inhibitor protein of cyclic AMP-dependent protein kinase. These results indicate that a calcium- and cyclic AMP-independent, labile “maturation-specific protein kinase” appeared before GVBD in maturing oocytes, and suggest its participation in the phosphorylation burst in vivo. The possible correlation of this kinase with maturation-promoting factor and chromosome condensation was discussed.     

Changes in protein synthesis and phosphorylation patterns during bovine oocyte maturation in vitro

Sequential protein synthesis and protein phosphorylation patterns were generated by radiolabelling bovine cumulus-oocyte complexes after various periods of culture with [35S]methionine and [32P]orthophosphate respectively. The radiolabelled oocytes were assessed for their nuclear status and used individually for gel electrophoresis. Marked changes in the protein synthesis patterns were observed exclusively after germinal vesicle breakdown (GVBD), whereas oocytes which remained in the germinal vesicle stage showed a consistent protein synthesis pattern. The changes were observed after 8 and 16 h or culture, shortly after GVBD and before first polar body extrusion. From 3 h of culture, dominant phosphoprotein bands with apparent molecular weights of 24,000 and two between 50,000 and 60,000 were observed. The latter bands displayed slight molecular weight changes, which were not closely time related. After GVBD, the phosphoprotein band with Mr 19,000 was no longer observed. This study demonstrates that specific changes in protein synthesis and protein phosphorylation are programmed during bovine oocyte 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.     

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.     

Analyses of mitogen-activated protein kinase function in the maturation of porcine oocytes

The function of mitogen-activated protein kinase (MAPK) during porcine oocyte maturation was examined by injecting oocytes with either mRNA or antisense RNA of porcine c-mos protein, an upstream kinase of MAPK. The RNAs were injected into the cytoplasm of porcine immature oocytes immediately after collection from ovaries, then the oocytes were cultured for maturation up to 48 h. The phosphorylation and activation of MAPK were observed at 6 h after injection of the c-mos mRNA injected-oocytes, whereas in control oocytes, MAPK activation was detected at 24 h of culture. The germinal vesicle breakdown (GVBD) rate at 24 h of culture was significantly higher in c-mos mRNA-injected oocytes than in control oocytes. In contrast, although injection of c-mos antisense RNA completely inhibited phosphorylation and activation of MAPK throughout the maturation period, the GVBD rate and its time course were the same in noninjected oocytes. The degree of maturation-promoting factor (MPF) activation was, however, very low in oocytes in the absence of MAPK activation. Most of those oocytes had both abnormal morphology and decondensed chromosomes at 48 h of culture. These results suggest that MAPK activation is not required for GVBD induction in porcine oocytes and that the major roles of MAPK during porcine oocyte maturation are to promote GVBD by increasing MPF activity and to arrest oocytes at the second metaphase.     

Two-dimensional polyacrylamide gel analysis of changes in protein phosphorylation during maturation of Xenopus oocytes

A three- to five-fold increase in non-cAMP-dependent protein phosphorylation has previously been found to occur in progesterone-treated oocytes shortly before germinal vesicle breakdown (GVBD) or immediately following maturation-promoting factor (MPF) injection. Analysis of phosphoprotein from 32Pi-labeled oocytes by both equilibrium and nonequilibrium two-dimensional gel electrophoresis revealed a large number of qualitative changes in phosphoproteins at GVBD, including both phosphorylation and dephosphorylation events. Time-course studies demonstrated that some of the new phosphoproteins appeared as early as 0.36 GVBD50, and all changes were stable at least through GVBD. The pattern of new phosphoproteins at GVBD was similar in oocytes microinjected with a partially purified preparation of MPF. A number of the new phosphoproteins were heat stable, which may facilitate their purification and characterization. These results support the hypothesis that key regulatory events during oocyte maturation are controlled by protein phosphorylation.     

Nature of the 1-Methyladenine-Requiring Phase in Maturation of Starfish Oocytes

Reinitiation of meiosis in starfish oocytes requires the continuous presence of 1-methyladenine (1-MeAde) in the surrounding medium for a definite period. The length of the 'hormone-dependent phase' (HDP) in Asterina pectinifera , which was defined as the time necessary for induction of 50% germinal vesicle breakdown (GVBD), was found to be about 11 min at 17°C, and 8 min at 20°C. Repeated treatments for shorter periods with 1-MeAde revealed that the action of this agent was cumulative, and that stable intermediate states between the unstimulated and fully stimulated levels existed during the HDP. Measurement of the stiffness of oocytes also demonstrated this stable intermediate state. Thus, there may be a factor(s) in the cytoplasm that accumulates continuously during the HDP and triggers GVBD when it reaches a critical level(s). When dithiothreitol (DTT) was used as an artificial maturation-inducing agent, the intermediate state was far less stable, suggesting a difference in the modes of action of 1-MeAde and DTT. Isotonic CaCl₂, the Ca²⁺ ionophore (A 23187) and methylxanthines, which are known to cause increase in intracellular Ca²⁺, had additive effects with 1-MeAde. These results suggest that part of the action of 1-MeAde is to release Ca²⁺ in the oocyte cytoplasm.     

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.     

Oocyte Competence to Maturation-inducing Hormone. I. Breakdown of Germinal Vesicles of Small Oocytes in Starfish,Asterina pectinifera*

1-Methyladenine (1-MeAde) is the endogenous maturation-inducing substance (MIS) in starfish. However, small oocytes have no competence to 1-MeAde even at the concentration of 10^?5M. Furthermore, when they were injected with cytoplasm of fully-grown (large) and maturing (1-MeAde-treated) oocytes, known to contain maturation-promoting factor (MPF), they did not undergo germinal vesicle breakdown (GVBD). On the other hand, germinal vesicles (GV) of the small oocytes underwent nuclear breakdown when the small oocytes were fused with the large maturing oocytes. Therefore it is concluded that the GV of the small oocytes are capable of undergoing nuclear breakdown in the presence of the sufficient MPF, but that the small oocytes can not amplify the injected MPF. Fused cells displayed particular shape changes during the course of nuclear breakdown of both the large and the small oocytes.     

In Vitro Induction of Starfish Oocyte Maturation by Cysteine Alkylesters

The effect of various disulfide-reducing agents including cysteine and its alkylesters on the induction of germinal vesicle breakdown (GVBD) in starfish ( Asterina pectinifera ) oocytes was investigated in vitro . Although cysteine did not induce GVBD, its alkylesters were effective. Cysteine alkylesters significantly mimicked the effect of 1-methyladenine (1-MeAde), the naturally occurring maturation-inducing hormone of starfish, on oocyte maturation. However, the effective concentrations and pH optimum for stimulation of oocyte maturation varied between 1-MeAde and the cysteine alkylesters. By comparing pKa values of the disulfide-reducing agents to pH of the medium, it is suggested that the redox potential of a disulfide-reducing agent is an important indicator its ability to induce oocyte maturation.
With the use of fluorescent probes for thiol groups, it was shown that the fluorescence in oocyte cortices increased within 5 min after administration of 1-MeAde. The fluorescence intensity in the cortices also increased after treatment with cysteine and its alkylesters, although the intensity was much stronger with the latter. Furthermore, both 1-MeAde and the disulfide-reducing agents were suggested to cause reduction of thiol groups within the plasma membrane as opposed to those on the external and internal surfaces. Thus, it is suggested that disulfide-reducing agents and 1-MeAde induce starfish oocyte maturation by changing the redox state of the thiol groups located within the oocyte plasma membrane.     

Characterization of polo-like kinase 1 during meiotic maturation of the mouse oocyte

We have characterized plk1 in mouse oocytes during meiotic maturation and after parthenogenetic activation until entry into the first mitotic division. Plk1 protein expression remains unchanged during maturation. However, two different isoforms can be identified by SDS-PAGE. A fast migrating form, present in the germinal vesicle, seems characteristic of interphase. A slower form appears as early as 30 min before germinal vesicle breakdown (GVBD), is maximal at GVBD, and is maintained throughout meiotic maturation. This form gradually disappears after exit from meiosis. The slow form corresponds to a phosphorylation since it disappears after alkaline phosphatase treatment. Plk1 activation, therefore, takes place before GVBD and MAPK activation since plk1 kinase activity correlates with its slow migrating phosphorylated form. However, plk1 phosphorylation is inhibited after treatment with two specific p34(cdc2) inhibitors, roscovitine and butyrolactone, suggesting plk1 involvement in the MPF autoamplification loop. During meiosis plk1 undergoes a cellular redistribution consistent with its putative targets. At the germinal vesicle stage, plk1 is found diffusely distributed in the cytoplasm and enriched in the nucleus and during prometaphase is localized to the spindle poles. At anaphase it relocates to the equatorial plate and is restricted to the postmitotic bridge at telophase. After parthenogenetic activation, plk1 becomes dephosphorylated and its activity drops progressively. Upon entry into the first mitotic M-phase at nuclear envelope breakdown plk1 is phosphorylated and there is an increase in its kinase activity. At the two-cell stage, the fast migrating form with weak kinase activity is present. In this work we show that plk1 is present in mouse oocytes during meiotic maturation and the first mitotic division. The variation of plk1 activity and subcellular localization during this period suggest its implication in the organization and progression of M-phase.     

Starfish oocyte maturation: 1-methyladenine triggers a drop of cAMP concentration related to the hormone-dependent period

Oocyte maturation (meiosis reinitiation) in starfish is induced by the natural hormone 1-methyladenine (1-MeAde). Oocytes of Evasterias troschelii contain 0.43 pmole cyclic AMP/mg protein and 0.47 pmole cyclic GMP/mg protein. Upon stimulation by 1-MeAde the oocytes undergo a moderate (10-30%) decrease in their cAMP concentration. The concentration of cGMP remains unaltered. Oocytes treated with forskolin, an activator of adenylate cyclase, increase their cAMP concentration over 35-fold, up to 16 pmole cAMP/mg protein. When stimulated by 1-MeAde these forskolin-pretreated oocytes undergo a major (50-70%) decrease in their cAMP concentration. A similar decrease is triggered by mimetics of 1-MeAde, such as dithiothreitol, arachidonic acid (AA), and 8-hydroxyeicosatetraenoic acid (8-HETE), but not by adenine which is inactive. 1-MeAde-stimulated oocytes of Pisaster ochraceus also undergo a decrease in cAMP content, the size of which is increased by forskolin. Although a decrease in cAMP begins at sub-threshold 1-MeAde concentrations, the maximal decrease occurs at the same concentration of 1-MeAde needed for maturation induction and a further 1000-fold increase of the 1-MeAde concentration has no further effect. Upon removal of 1-MeAde, the cAMP concentration immediately increases to its original level. Sequential addition and removal of 1-MeAde triggers a sequential decrease and increase of the cAMP concentration, illustrating the continuous requirement for 1-MeAde for eliciting the decrease. Successive additions of 1-MeAde, however, do not trigger further decreases of the cAMP concentration. The temperature dependences of the cAMP concentration decrease and of the hormone-dependent period (HDP; the time of contact with 1-MeAde required for induction of maturation) are closely related. Forskolin, which increases the cAMP concentration, also increases the duration of the HDP (2.5-fold), delays the time course of protein phosphorylation burst and germinal vesicle breakdown, and inhibits AA- and 8-HETE-induced maturation. We conclude that 1-MeAde triggers a drop in cAMP concentration, which is tightly associated with the hormone-dependent period of oocyte maturation.