Abstract
Progesterone-induced meiotic maturation of Xenopus oocytes requires the synthesis of new proteins, such as Mos and cyclin B. Synthesis of Mos is thought to be necessary and sufficient for meiotic maturation; however, it has recently been proposed that newly synthesized proteins binding to p34cdc2 could be involved in a signaling pathway that triggers the activation of maturation-promoting factor. We focused our attention on cyclin B proteins because they are synthesized in response to progesterone, they bind to p34cdc2, and their microinjection into resting oocytes induces meiotic maturation. We investigated cyclin B accumulation in response to progesterone in the absence of maturation-promoting factor–induced feedback. We report here that the cdk inhibitor p21cip1, when microinjected into immature Xenopus oocytes, blocks germinal vesicle breakdown induced by progesterone, by maturation-promoting factor transfer, or by injection of okadaic acid. After microinjection of p21cip1, progesterone fails to induce the activation of MAPK or p34cdc2, and Mos does not accumulate. In contrast, the level of cyclin B1 increases normally in a manner dependent on down-regulation of cAMP-dependent protein kinase but independent of cap-ribose methylation of mRNA.
INTRODUCTION
Xenopus fully grown oocytes are naturally arrested in prophase of the first meiotic division (prophase I). In response to progesterone, they undergo meiotic maturation and then arrest a second time in metaphase of the second meiotic division (metaphase II) until fertilization. The steroid hormone progesterone induces with a lag of 3–5 h activation of maturation-promoting factor (MPF), breakdown of the germinal vesicle (GVBD), and entry into M-phase of the first meiotic division (see Masui and Clarke, 1979, for review). MPF is a protein kinase composed of a catalytic subunit, p34cdc2 (Dunphy et al., 1988; Gautier et al., 1988; Draetta et al., 1989; Meijer et al., 1989), and a regulatory subunit, cyclin B (Gautier et al., 1990), that accumulates during terminal oocyte growth to form a complex called preMPF (Wasserman and Masui, 1975; Gerhart et al., 1984; Gautier and Maller, 1991). PreMPF is kept inactive by inhibitory phosphorylations on threonine 14 and tyrosine 15 of the p34cdc2 subunit. The conversion of preMPF into active MPF occurs several hours after progesterone stimulation, just before GVBD; it depends on activation of the protein phosphatase Cdc25, which catalyzes the dephosphorylation of threonine 14 and tyrosine 15 of p34cdc2. At about the same time, i.e., around GVBD, MAPK becomes fully activated (Gotoh et al., 1991; Matsuda et al., 1992; Roy et al., 1996). Little is known about the transduction pathway that connects the initial effects of progesterone to activation of preMPF.
It is well established that progesterone-induced maturation depends on the synthesis of new proteins and is inhibited by the cAMP pathway (Maller and Krebs, 1977). The protein kinase Mos is the only newly synthesized protein that has been shown to be necessary for progesterone-induced maturation (Sagata et al., 1988). Mos is a MAP kinase kinase kinase that leads to the activation of MAPK through the activation of MAP kinase kinase (also called MEK) (Nebreda et al., 1993; Posada et al., 1993; Shibuya and Ruderman, 1993); therefore, it is generally proposed that in ovo the translation of stored mos mRNA induces MAPK activation in maturing oocytes. In the absence of p34cdc2 activity, Mos is synthesized but does not attain normal levels (Nebreda et al., 1995). This raises the question of whether the accumulation of Mos is stimulated by p34cdc2 activity. In theory, the accumulation of a protein absolutely required for preMPF activation must depend on progesterone stimulation and be independent of p34cdc2 activity. It is important, therefore, to distinguish the newly made proteins that accumulate during the lag period before p34cdc2 activation from those whose accumulation is stimulated downstream of p34cdc2 activation.
We report here a direct approach for identifying proteins that accumulate independently of p34cdc2 activity after progesterone stimulation. For this purpose, we microinjected into prophase oocytes recombinant p21cip1, a well-known inhibitor of cdk/cyclin complexes (Xiong et al., 1993). We show that microinjected p21cip1 binds endogenous p34cdc2/cyclin complexes and prevents their activation in ovo. Therefore, we used p21cip1 as a tool to study the accumulation of proteins such as cyclin B1, cyclin B2, and Mos under conditions in which progesterone-induced MPF activation and GVBD were abolished.
MATERIALS AND METHODS
Materials
Xenopus laevis adult females (Centre National de la Recherche Scientifique, Rennes, France) were bred and maintained under laboratory conditions. Reagents, unless otherwise specified, were from Sigma (Saint Quentin Fallavier, France).
Purification of Recombinant Proteins
Cip1 cloned into the NcoI site of pGEX-KG (a kind gift of Dr. Tim Hunt) was transfected into TG1 cells. Expression of the GST-p21cip1 fusion protein was induced by 0.1 mM isopropyl-β-d-thiogalactopyranoside for 3 h at room temperature. After centrifugation at 10,000 × g for 15 min at 4°C, the pellets were frozen. Bacteria were lysed in 50 mM Tris-HCl, pH 7.3, 0.1 M NaCl, 1 mM EDTA, 1 mM EGTA, 5 mM benzamidine, 1 mM 4-(2-aminoethyl)-benzenesulfonyl fluoride (Pentapharm, Basel, Switzerland), 1 mg/ml lysozyme (Boehringer Mannheim, Indianapolis, IN) by sonication in the presence of detergents (0.5% Triton, 0.5% NP40). After ultracentrifugation (100,000 × g, 4°C, 1 h), the supernatant containing recombinant p21cip1 was loaded onto an equilibrated glutathione-agarose column, washed, and eluted with 20 mM Tris-HCl, pH 9, 0.5 M NaCl, 0.1 mM EDTA, 0.1 mM EGTA, 1 mM DTT, 10 mM glutathione. The purified proteins were concentrated with a Microcon-50 (Millipore, Saint Quentin en Yvelines, France) to a final concentration of 0.75 mg/ml. MBP-Mos was purified as described by Roy et al. (1996).
Synthesis of [35S]Methionine-labeled Cyclin B1
Twenty micrograms of circular DNA containing the sequence coding for Xenopus cyclin B1 were incubated for 3 h at 30°C in 200 μl of TNT-coupled reticulocyte lysate system containing T7 polymerase (Promega, Charbonnieres, France) in the presence of 400 μCi of [35S]methionine (New England Nuclear, Boston, MA). The newly synthesized protein was concentrated and washed on Microcon-10 (Millipore) before injection into oocytes.
Oocyte Treatment
Isolated oocytes were prepared and maintained as described (Jessus et al., 1987). Fully grown oocytes, referred to as “prophase oocytes,” were injected or not with p21cip1 to an internal concentration of 1 μM. One hour after microinjection, oocytes were induced to mature either by the addition of 1 μM progesterone in the medium, by MPF transfer, by microinjection of 50 nl of 10−5 M okadaic acid (OA) (ICN, Orsay, France), by microinjection of the recombinant thermostable inhibitor of the catalytic subunit of cAMP-dependent protein kinase (PKI) from rabbit muscle (8 pmol/oocyte), or by microinjection of recombinant MBP-Mos (50 μg/oocyte).
In other experiments, maturation was inhibited by microinjection of 10 ng of the catalytic subunit of PKA (PKAc) per oocyte (Promega) 1 h before the addition of progesterone, by preincubation in the presence of 0.75 mM S-isobutylthioadenosine (SIBA) for 2 h, or by preincubation in the presence of 100 μg/ml cycloheximide for 1 h.
Maturation was monitored by the appearance of a white spot at the animal pole of the oocyte. Oocytes were collected when 100% GVBD was reached in control oocytes, or at metaphase II (2 h after 100% GVBD in progesterone controls), or at the indicated times. Oocytes matured in vitro (metaphase II) were injected or not with p21cip1 to an internal concentration of 1 μM in the presence of 100 mM EGTA. Oocytes were homogenized at 4°C in 5 volumes of extraction buffer (80 mM β-glycerophosphate, 20 mM EGTA, 15 mM MgCl2, 1 mM DTT, pH 7.3, 25 μg/ml leupeptin and aprotinin, 10 μg/ml pepstatin, 1 mM benzamidine, 1 μM 4-(2 aminoethyl)-benzenesulfonyl fluoride [Pentapharm]) and centrifuged at 7000 rpm for 15 min at 4°C. Clear supernatant was used for Western blot analysis or for recovery of proteins on glutathione-agarose beads.
Histone H1 Kinase Assays
The supernatant (15 μl, i.e., three oocytes) was collected for p13suc1 binding followed by histone H1 kinase assays in the presence of [γ-32P]ATP (New England Nuclear) according to Jessus et al. (1991).
Immunoblotting
Western blotting was performed with anti-Mos, anti-MAPK (Santa Cruz Biotech, Santa Cruz, CA), anti-p34cdc2 (a kind gift from Dr. Tim Hunt, Imperial Research Fond, London, United Kingdom), anti-cyclin B1, anti-cyclin B2, or anti-cyclin A antibodies. The antisera raised in sheep against Xenopus cyclins A, B1, and B2 have been described by Gautier et al. (1990); antisera to cyclins B1 and B2 were blot purified using recombinant cyclin B1 and B2 as described (Olmsted, 1981; Rempel et al., 1995). Proteins were subjected to electrophoresis in Laemmli buffer (Laemmli, 1970) on a 12.5% SDS-PAGE Anderson gel (Anderson et al., 1973) or on a 15% SDS-PAGE Laemmli gel (Laemmli, 1970) and then transferred to nitrocellulose filters (Schleicher & Schull, Ecquevilly, France). The proteins of interest were visualized by use of the appropriate primary antibody, HRP-conjugated secondary antibody (Jackson Immunoresearch, West Grove, PA), and renaissance chemoluminescence reagent (New England Nuclear). We observed that the amount of cyclin B1 detected in prophase-arrested oocytes varied from female to female. Cyclin B1 was resolved as two bands on 12.5% Anderson gels and as one band on 15% Laemmli gels (see Figure 6, A and B).
Binding of GST-p21cip1 to Glutathione-Agarose Beads
Fifteen milligrams of glutathione-agarose beads saturated with extraction buffer containing 10% BSA was added to a supernatant prepared from 30 oocytes. After incubation for 2 h, the beads were washed three times with 20 mM Tris, 5 mM EDTA, 1% Triton X-100 containing 100 mM NaCl, then 1 M NaCl, and finally 100 mM NaCl. Proteins bound to the beads were eluted with SDS-sample buffer, subjected to electrophoresis, and analyzed by Western blotting.
Autoradiography of [35S]Methionine-labeled Cyclin B1
Oocytes injected with [35S]methionine-labeled cyclin B1 were collected at different times, homogenized, and analyzed by autoradiography on a 12.5% SDS-PAGE Anderson gel (Anderson et al., 1973). An amount equivalent to four oocytes was loaded on each lane.
RESULTS
p21cip1 Inhibits Progesterone-induced Maturation
Human p21cip1 is an inhibitor of all cdk/cyclin complexes (Xiong et al., 1993). To determine whether p21cip1 could inhibit oocyte maturation, recombinant p21cip1 prepared as a GST fusion protein (GST-p21cip1) was microinjected into fully grown prophase oocytes. At a final intracellular concentration of 1 μM (0.75 mg/ml in the pipette), p21cip1 totally inhibited progesterone-induced GVBD (Figure 1A). This effect was obtained with oocytes isolated from more than 30 different females and was dose dependent, with a 50% inhibitory concentration of ∼0.4 μM. The activity of p34cdc2 was assayed by measuring histone H1 kinase activity in progesterone-treated control and p21cip1-injected oocytes (Figure 1B). Histone H1 kinase activity was high 2 h after GVBD in control oocytes. In contrast, in p21cip1-injected oocytes, preMPF activation did not occur and activity remained at the basal level, comparable to that in prophase control oocytes. Histone H1 kinase activation was blocked in p21cip1-injected oocytes for as long as 24 h in the continuous presence of progesterone.
p21cip1 Interacts with p34cdc2/Cyclin Complexes and Inhibits MPF Autoamplification but Not the Mos-induced MAPK Pathway
We next examined whether injected p21cip1 inhibits p34cdc2 activation and GVBD by directly binding to endogenous p34cdc2/cyclin complexes. p21cip1 was microinjected into prophase oocytes; 1 h later, oocytes were collected, homogenized, and centrifuged, and the supernatant was incubated in the presence of glutathione-agarose beads. Proteins bound to the beads were then analyzed by immunoblotting with various antibodies. Microinjected p21cip1 was recovered in association with the glutathione beads. p34cdc2, cyclin B1, and cyclin B2 were also bound to the beads (Figure 2, A–C). A similar experiment was also performed with oocytes matured in vitro and arrested in metaphase II. As in prophase oocytes, p34cdc2/cyclin B2 and p34cdc2/cyclin B1 were recovered on the beads (Figure 2, A–C); as expected, cyclin A, which is absent in prophase oocytes and is synthesized de novo during maturation, was also bound to the beads (Figure 2D). These results indicate that p21cip1 acts in ovo by direct binding to active or inactive p34cdc2/cyclin complexes.
We next verified whether p21cip1 could inhibit the MAPK pathway. When recombinant MBP-Mos was injected into p21cip1-treated oocytes, activation of MPF and GVBD were blocked. However, the electrophoretic mobility shift of MAPK was still observed (Figure 2E). Moreover, it has been shown that the activity of oocyte MAPK measured by an in-gel assay was not affected by the presence of p21cip1 (Karaiskou et al., 1998). These results show that p21cip1 does not inhibit components of the MAPK pathway.
If p21cip1 acts by direct binding to MPF, then it should also inhibit meiotic maturation induced by MPF transfer because it also requires activation of preMPF. When a small amount of cytoplasm taken from matured oocytes is microinjected into prophase oocytes, p34cdc2 activation and GVBD occur less than 3 h later (Masui and Markert, 1971). When oocytes were first microinjected with p21cip1 and then 1 h later with 50 nl of cytoplasm taken from a matured oocyte, GVBD did not occur, H1 kinase activity was not increased, and the electrophoretic mobility shift of cyclin B2 was blocked (Figure 3, A and B).
OA is an inhibitor of types 1 and 2A Ser/Thr protein phosphatases (Bialojan and Takai, 1988). Microinjection of 50 nl of 10−5 M OA into prophase oocytes induces rapid p34cdc2 activation (Goris et al., 1989) and a subsequent cytologically abnormal GVBD (Rime et al., 1990). It has been proposed that microinjected OA, by promoting phosphorylation/activation of Cdc25, initiates the positive feedback loop that controls activation of p34cdc2 in ovo (Izumi and Maller, 1993). When OA was microinjected into p21cip1-injected oocytes, p34cdc2 activation and the electrophoretic mobility shift of cyclin B2 were totally blocked for at least 8 h (Figure 3, C and D).
Progesterone Induces Accumulation of Cyclin B1 in p21cip1-microinjected Oocytes
As shown above, microinjection of recombinant p21cip1 inhibited preMPF activation induced by progesterone. The electrophoretic mobility shift of cyclin B2, which normally correlates with p34cdc2 activation (Gautier et al., 1990; Roy et al., 1996), was also totally blocked (Figure 4A). Although the synthesis of Mos can be detected before the conversion of preMPF to active MPF (Sagata et al., 1989; Nebreda et al., 1995), accumulation of Mos does not become detectable before GVBD (Roy et al., 1996). Surprisingly, in p21cip1-injected oocytes, the level of Mos did not increase after progesterone stimulation (Figure 4B); as expected from the absence of Mos under these conditions, the electrophoretic mobility of MAPK was not retarded (Figure 4C). Therefore, the progesterone-dependent accumulation of Mos does not occur in the absence of p34cdc2 activity. Unexpectedly, however, in p21cip1-inhibited oocytes, cyclin B1 accumulated normally after progesterone treatment (Figure 4D). The time course of the accumulation of cyclin B1 in control progesterone-treated oocytes and in p21cip1-injected progesterone-treated oocytes was similar (Figure 5). Interestingly, in both control (Kobayashi et al., 1991) and p21cip1-inhibited oocytes, the accumulation of cyclin B1 after progesterone stimulation takes place after a lag period of several hours and is thus not an early effect of the hormone. These results show that accumulation of cyclin B1 is regulated differently from that of Mos in response to progesterone. In particular, the amount of cyclin B1 is up-regulated by progesterone independently of p34cdc2 and MAPK activities.
It has been reported that SIBA, a methyltransferase inhibitor, prevents mRNA cap-ribose methylation, Mos synthesis, and oocyte maturation (Kuge et al., 1998). Therefore, we examined the effect of SIBA on the accumulation of cyclin B1. Oocytes were preincubated or not in the presence of 750 μM SIBA for 2 h, p21cip1 was then microinjected, and 1 h later progesterone was added or not in the continuous presence of SIBA. As expected, meiotic maturation induced by progesterone was totally prevented by SIBA. As reported by Kuge et al. (1998), accumulation of Mos was blocked (Figure 6A); however, accumulation of cyclin B1 was still observed (Figure 6B). This result shows that the increased level of cyclin B1 does not depend on new cap-ribose methylation of mRNAs, not even that of mos mRNA.
Progesterone Does Not Change the Stability of Microinjected Cyclin B1
We then addressed the question of whether cyclin B1 accumulation was the consequence of either the increased rate of synthesis and/or a decrease in the rate of degradation. Oocytes were first incubated in the presence of cycloheximide, a strong inhibitor of protein synthesis. They were then injected or not with p21cip1, and 1 h later they were incubated in the presence of progesterone. As expected, cyclin B1 did not accumulate (Figure 7A). This finding shows that cyclin B1 accumulation is a consequence of a new synthesis and does not result from decreased degradation.
To estimate the in ovo stability of cyclin B1, [35S]methionine-labeled cyclin B1 was injected into prophase oocytes in the presence or in the absence of p21cip1, stimulated or not with progesterone. We injected trace amounts of radioactive cyclin B1 that were not able to induce meiotic maturation. In prophase oocytes, ectopic cyclin B1 remained stable from more than 20 h (Figure 7B, upper left panel). When oocytes were first microinjected with radioactive cyclin B1 and then treated with progesterone, cyclin B1 was stable until GVBD, after which it was abruptly degraded (Figure 7B, upper right panel). This result demonstrates that the ectopic protein is the target of the anaphase-promoting complex (APC), which is activated at the metaphase/anaphase transition in meiosis I and promotes the degradation of cyclins (Furuno et al., 1994; Roy et al., 1996; Thibier et al., 1997). Radioactive microinjected cyclin B1 was as stable in p21cip1-injected oocytes whether progesterone was added or not (Figure 7B, lower panels). Although exogenous radioactive cyclin B1 levels remained stable in oocytes treated with progesterone in the presence of p21cip1, it was ascertained by Western blotting that under these conditions endogenous cyclin B1 accumulated after progesterone stimulation (Figure 7C). These results suggest that cyclin B1 accumulation induced by progesterone does not involve a change in the stability of cyclin B1.
PKA Inhibits the Accumulation of Cyclin B1
The decrease in cAMP concentration and the subsequent inactivation of PKA are the first early events known to be induced by progesterone. To evaluate whether cyclin B1 accumulation is regulated by PKA activity, we microinjected the thermostable inhibitor of the catalytic subunit of PKA (PKI) into oocytes. Under these conditions, PKI induces 100% of the oocytes to undergo maturation (Maller and Krebs, 1977; Huchon et al., 1981). However, coinjection of p21cip1 blocked the ability of PKI to induce maturation. It also blocked the accumulation of Mos induced by PKI, but the increase in cyclin B1 was not affected (Figure 8A). The inhibition of PKA by progesterone treatment, therefore, is sufficient to promote the accumulation of cyclin B1. To determine whether this inhibition is also necessary, 10 ng of PKAc was microinjected per oocyte. Under these conditions, PKAc inhibited progesterone-induced maturation, and the accumulation of both Mos and cyclin B1 was prevented (Figure 8B). These results clearly show that the accumulation of cyclin B1 requires a decrease in the activity of PKA.
MPF Transfer or OA Induces Accumulation of Cyclin B1
Because MPF transfer is known to induce all the events of meiotic maturation (Masui and Markert, 1971), it was interesting to investigate the effects of MPF transfer on cyclin B1 accumulation. As shown in Figure 9A, when cytoplasm taken from matured oocytes was microinjected into prophase oocytes, cyclin B1 accumulated in the presence or in the absence of p21cip1. In contrast, in the presence of p21cip1 Mos did not accumulate and MAPK remained in its inactive, unshifted form (Figure 9, B and C). Similar results were obtained when OA was microinjected into p21cip1-treated oocytes (Figure 9, D–F). This argues that a phosphorylation step might be involved in the pathway leading to the accumulation of cyclin B1.
DISCUSSION
In this study, we developed a new experimental approach to the study of proteins whose abundance is regulated by progesterone during the lag period preceding p34cdc2 activation in Xenopus oocytes. This approach used the cdk inhibitor p21cip1 to inhibit the activation of preMPF and facilitated the study of the early effects of progesterone. The results show that the level of cyclin B1 is directly regulated by initial progesterone stimulation and does not depend on increased p34cdc2 activity. In contrast, the progesterone-dependent increase of Mos protein was totally inhibited in p21cip1-treated oocytes, indicating that in vivo the activity of p34cdc2 is absolutely required to promote Mos accumulation. Together, these results indicate that regulation of the levels of Mos and cyclin B1 is mediated by two different biochemical pathways.
p21cip1 binds to and inhibits in vitro and in vivo a number of cdk/cyclin complexes (Gu et al., 1993; Xiong et al., 1993; Su et al., 1995). Recently, it was reported that microinjection of p21cip1 into Xenopus oocytes at a final intracellular concentration of 0.1 μM does not inhibit progesterone-induced maturation but totally inhibits the activation of cdk2 that normally occurs after GVBD (Furuno et al., 1997). Because in vitro the affinity of p21cip1 for cdk2/cyclin complexes is higher than its affinity for p34cdc2/cyclin complexes (Su et al., 1995), we microinjected a higher concentration of p21cip1 (1 μM) to inhibit in ovo the activation of p34cdc2/cyclin B complexes. We found that at this concentration p21cip1 binds to endogenous p34cdc2/cyclin B complexes and totally inhibits GVBD and activation of histone H1 kinase. Therefore, under our conditions, p21cip1 acts by binding and inhibiting p34cdc2. This conclusion is strengthened by the observation that p21cip1 also inhibits GVBD after MPF transfer or OA microinjection, i.e., experimental conditions that bypass the early effects of progesterone.
It has been shown that the activity of MAPK depends on a critical threshold of Mos protein (Chen and Cooper, 1997; Ferrell and Bhatt, 1997). The accumulation of Mos leading to this threshold level could result from regulation of the synthesis and/or turnover of the protein. Nebreda et al. (1995) have shown that overexpression of a kinase-inactive p34cdc2 (K33R) or microinjection of the A17 anti-p34cdc2 antibody inhibits progesterone-induced GVBD, activation of p34cdc2, accumulation of Mos, and the MAPK cascade. Interestingly, in the presence of the A17 anti-p34cdc2 antibody, progesterone stimulates the synthesis of 35S-labeled Mos, as detected by immunoprecipitation, but its accumulation is not detectable by immunoblotting (Nebreda et al., 1995). A main finding presented here is that Mos accumulation also does not occur when activation of p34cdc2 is blocked by p21cip1, arguing that the Mos/MAP kinase kinase/MAPK pathway is under the control of p34cdc2 activity (Figure 10). Although not studied directly in this paper, the accumulation of Mos may depend on a change in stability. Indeed, Nishizawa et al. (1993) reported that phosphorylation at a proline-directed site near the N terminus might regulate stability.
In contrast to the p34cdc2-dependent accumulation of Mos and activation of the MAPK pathway, we show in this report that the accumulation of cyclin B1 induced by progesterone is independent of p34cdc2 activity. It is also independent of the activation of the MAPK pathway because both Mos accumulation and MAPK activation were blocked by p21cip1. This was confirmed by the injection of mos-specific antisense oligonucleotides into prophase oocytes in the presence of progesterone. Under these conditions and as previously shown (Sagata et al., 1988; Roy et al., 1996), p34cdc2 activation, GVBD, and MAPK activation normally induced by progesterone were inhibited, but the accumulation of cyclin B1 was still observed (our unpublished results). Taken together, these results show that cyclin B1 accumulation occurs in response to progesterone independently of p34cdc2 activity (Figure 10).
The discrepancy between Mos and cyclin B1 protein accumulation is also reflected at the mRNA level. Barkoff et al. (1998) reported that polyadenylation of mos mRNA is not sufficient for accumulation of the protein in the absence of progesterone. Moreover, when meiotic maturation is inhibited by the presence of kinase-inactive p34cdc2 (K33R), mos mRNA is still polyadenylated in response to progesterone (Ballantyne et al., 1997) but the protein does not accumulate (Nebreda et al., 1995). Conversely, under the same conditions, cyclin B1 mRNA does not undergo additional polyadenylation (Ballantyne et al., 1997) but the protein does accumulate (Nebreda et al., 1995). Furthermore, it has been shown that inhibition of cap-ribose methylation by SIBA prevents mos mRNA translation (Kuge et al., 1998); in contrast, our results demonstrate that, unlike Mos, cyclin B1 accumulates normally in the presence of SIBA. Thus, polyadenylation and cap-ribose methylation appear to be necessary but not sufficient for the accumulation of Mos, whereas the level of cyclin B1 can increase in the absence of polyadenylation or cap-ribose methylation of mRNA. Accumulation of cyclin B1 occurs over several hours. Our results with injected cyclin B1 suggest that the accumulation of cyclin B1 induced by progesterone in the presence of p21cip1 does not involve a decreased rate of degradation. However, we cannot rigorously exclude the possibility that a slight change in the balance between synthesis and degradation over several hours could contribute to the accumulation of cyclin B1 induced by progesterone.
One biochemical change known to control Xenopus oocyte maturation is a decrease in the activity of PKA. Maller and Krebs (1977) showed that PKAc inhibits progesterone-induced maturation, whereas PKI and the regulatory subunit of PKA induce meiotic maturation directly in the absence of progesterone. A decrease in cAMP concentration after progesterone addition correlates with the inhibition of PKA and is the first early event known to occur upstream of Mos synthesis and p34cdc2 activation (Speaker and Butcher, 1977; Maller et al., 1979). The results in this paper provide evidence that the accumulation of cyclin B1 is another response of the oocyte to progesterone that is independent of Mos synthesis and p34cdc2 activation. We also analyzed directly the effects of an increase or decrease in PKA activity on cyclin B1 accumulation. Our results demonstrate that inhibition of PKA is sufficient to allow cyclin B1 accumulation when p34cdc2 activation is inhibited by p21cip1. The reciprocal experiment shows that injection of PKAc prevents the accumulation of cyclin B1 induced by progesterone. The hormone, therefore, triggers cyclin B1 accumulation by acting through a decrease in PKA activity (Figure 10). This again differentiates cyclin B1 from Mos in terms of regulation, because it was recently shown that PKA does not exert any inhibitory effect on Mos translation induced by exogenous Mos injection (Faure et al., 1998). However, GVBD does not occur when exogenous Mos is injected in the presence of PKAc (Daar et al., 1993). These results favor the view that accumulation of cyclin B1 may be required for Mos to trigger meiotic maturation.
What could be the functional role of cyclin B1 accumulation? It is well established that microinjection of cyclin B protein induces GVBD in the absence of protein synthesis (Roy et al., 1991). Our findings demonstrate that cyclin B1 accumulates in response to progesterone in the absence of MPF activation. Furthermore, a recent report by de Moor and Richter (1999) shows that the stimulation of endogenous cyclin B1 translation is sufficient to induce meiotic maturation.
Together, these experimental data suggest that cyclin B1 accumulation could be a physiological trigger of preMPF activation in oocytes. This pathway is indeed the shortest link between progesterone and preMPF activation (Figure 10).
Recently, a new cdk2-interacting protein encoded by the spy1 gene was cloned in Xenopus (Lenormand et al., 1999). The spy1 mRNA is capable of inducing MAPK and MPF activation as well as triggering meiotic maturation when injected into prophase oocytes, with a kinetic close to the one observed after cyclin B mRNA microinjection. Although there is no evidence at this time that spy1 protein is present and/or translated in oocytes, this protein represents a new potential player in the transduction pathway leading to MPF activation.
In summary, the accumulation of cyclin B1 represents an early step in the transduction pathway induced by progesterone in the oocyte. It clearly lies downstream of the decrease in PKA activity induced by the hormone. It is significant that this accumulation is independent of the mechanisms that lead to Mos accumulation, including stimulation of cap-ribose methylation. Additional studies on the mechanism of cyclin B1 accumulation should advance our understanding of the signal transduction pathways regulated by progesterone during oocyte maturation.
ACKNOWLEDGMENTS
We are grateful to Eleanor Erikson for critically reading the manuscript. This work was supported by the Centre National de la Recherche Scientifique, the Institut National de la Recherche Agronomique, the Université Pierre et Marie Curie, and by grants from the National Institutes of Health (GM26743 and DK28353). J.L.M. is an investigator of the Howard Hughes Medical Institute.
Abbreviations used:
- GVBD
germinal vesicle breakdown
- MPF
maturation-promoting factor
- OA
okadaic acid
- PKA
cAMP-dependent protein kinase
- PKAc
catalytic subunit of cAMP-dependent protein kinase
- PKI
thermostable inhibitor of the catalytic subunit of cAMP-dependent protein kinase
- SIBA
S-isobutylthioadenosine
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