A novel regulatory element determines the timing of Mos mRNA translation during Xenopus oocyte maturation

Progression through vertebrate oocyte maturation requires that pre-existing, maternally derived mRNAs be translated in a strict temporal order. The mechanism that controls the timing of oocyte mRNA translation is unknown. In this study we show that the early translational induction of the mRNA encoding the Mos proto-oncogene is mediated through a novel regulatory element within the 3' untranslated region of the Mos mRNA. This novel element is responsive to the MAP kinase signaling pathway and is distinct from the late acting, cdc2-responsive, cytoplasmic polyadenylation element. Our findings suggest that the timing of maternal mRNA translation is controlled through signal transduction pathways targeting distinct 3' UTR mRNA elements.     

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.     

Xenopus oocyte maturation: new lessons from a good egg.

Fully grown Xenopus oocytes can remain in their immature state essentially indefinitely, or, in response to the steroid hormone progesterone, can be induced to develop into fertilizable eggs. This process is termed oocyte maturation. Oocyte maturation is initiated by a novel plasma membrane steroid hormone receptor. Progesterone brings about inhibition of adenylate cyclase and activation of the Mos/MEK1/p42 MAP kinase cascade, which ultimately brings about the activation of the universal M phase trigger Cdc2/cyclin B. Oocyte maturation provides an interesting example of how signaling cascades entrain the cell cycle clock to environmental changes.     

Xenopus oocyte maturation does not require new cyclin synthesis

Progesterone induces fully grown, stage VI, Xenopus oocytes to pass through meiosis I and arrest in metaphase of meiosis II. Protein synthesis is required twice in this process: in order to activate maturation promoting factor (MPF) which induces meiosis I, and then again after the completion of meiosis I to reactivate MPF in order to induce meiosis II. We have used antisense oligonucleotides to destroy maternal stores of cyclin mRNAs, and demonstrate that new cyclin synthesis is not required for entry into either meiosis I or II. This finding is consistent with the demonstration that stage VI oocytes contain a store of B-type cyclin polypeptides (Kobayashi, H., J. Minshull, C. Ford, R. Golsteyn, R. Poon, and T. Hunt. 1991. J. Cell Biol. 114:755-765). Although approximately 70% of cyclin B2 is destroyed at first meiosis, the surviving fraction, together with a larger pool of surviving cyclin B1, must be sufficient to allow the reactivation of MPF and induce entry into second meiotic metaphase. Since stage VI oocytes do not contain any cyclin A, our results show that cyclin A is not required for meiosis in Xenopus. We discuss the possible nature of the proteins whose synthesis is required to induce meiosis I and II.     

The C. elegans Myt1 ortholog is required for the proper timing of oocyte maturation

Maturation promoting factor (MPF), a complex of cyclin-dependent kinase 1 and cyclin B, drives oocyte maturation in all animals. Mechanisms to block MPF activation in developing oocytes must exist to prevent precocious cell cycle progression prior to oocyte maturation and fertilization. This study sought to determine the developmental consequences of precociously activating MPF in oocytes prior to fertilization. Whereas depletion of Myt1 in Xenopus oocytes causes nuclear envelope breakdown in vitro, we found that depletion of the Myt1 ortholog WEE-1.3 in C. elegans hermaphrodites causes precocious oocyte maturation in vivo. Although such oocytes are ovulated, they are fertilization incompetent. We have also observed novel phenotypes in these precociously maturing oocytes, such as chromosome coalescence, aberrant meiotic spindle organization, and the expression of a meiosis II post-fertilization marker. Furthermore, co-depletion studies of CDK-1 and WEE-1.3 demonstrate that WEE-1.3 is dispensable in the absence of CDK-1, suggesting that CDK-1 is a major target of WEE-1.3 in C. elegans oocytes.     

Requirement for phosphorylation of cyclin B1 for Xenopus oocyte maturation.

Maturation-promoting factor, consisting of cdc2 protein kinase and a regulatory B-type cyclin, is a universal regulator of meiosis and mitosis in eukaryotes. In Xenopus, there are two subtypes of B-type cyclins, designated B1 and B2, both of which are phosphorylated. In this study, we have investigated the biological significance of this phosphorylation for Xenopus cyclin B1 during meiotic maturation. We have used a combination of site-directed mutagenesis and phosphopeptide-mapping to identify serine residues 2, 94, 96, 101, and 113 as presumptive phosphorylation sites, and together these sites account for all cyclin B1 phosphorylation in oocytes before germinal vesicle breakdown (GVBD). Single Ser-->Ala mutants as well as multiple site mutants have been constructed and characterized. Phosphorylation of cyclin B1 appears to be required for Xenopus oocyte maturation, based on the significantly diminished ability of the quintuple Ala mutant to induce oocyte maturation. Furthermore, partial phosphorylation of these five sites is sufficient to meet this requirement. Phosphorylation of cyclin B1 is not required for cdc2 kinase activity, for binding to cdc2 protein, for stability of cyclin B1 before GVBD, or for destruction of cyclin B1 after GVBD or after egg activation. A quintuple Glu mutant was also constructed, with serine residues 2, 94, 96, 101, and 113 mutated to Glu. In contrast to the quintuple Ala mutant, the quintuple Glu mutant was able to induce oocyte maturation efficiently, and with more rapid kinetics than wild-type cyclin B1. These data confirm that phosphorylation, as mimicked by Ser-->Glu mutations, confers enhanced biological activity to cyclin B1. Possible roles of cyclin B1 phosphorylation are discussed that might account for the increased biological activity of the quintuple Glu mutant.     

A possible role for Mg2+ ions in the induction of meiotic maturation of Xenopus oocyte

Progesterone induces in vitro the meiotic cell division of Xenopus full-grown oocytes. Microinjection into oocyte of a solution containing Mg2+ (20 mM) facilitates by one order of magnitude the dose of progesterone which induces 50% of germinal vesicle breakdown. Microinjected in the absence of hormone, Mg2+ and also Mn2+ can induce maturation with efficiencies of, respectively, 24% (SEM = 8; n = 13) and 70% (SEM = 6; n = 23). The dose-response curves of cation-induction of maturation show an optimum of 20 mM for Mg2+ and 15 mM for Mn2+ (pipet concentration); higher doses were less active. Cation-induction of maturation is inhibited when oocytes are preincubated with cholera toxin (500 ng/ml); nevertheless, it cannot be interpreted at the level of cAMP, since both Mg2+ and Mn2+ microinjections provoke an increase in the oocyte cAMP content. Mg2+ induction of maturation is more efficient when oocytes are incubated in trimethylamine at pH 8.2, which is known to increase intracellular pH suggesting an action at the level of alkali pH-sensitive enzymes. Altogether, our results indicate a positive role for Mg2+ ions in the induction of oocyte maturation and raise an attractive hypothesis about the respective roles of cAMP and Mg2+ changes involved in the mechanism of progesterone action. Our results also show that co-injection of 2-glycerophosphate and Mg2+ ions, which are both commonly used in the preparation of the MPF mitotic factors from dividing cells, induces oocyte maturation more efficiently than Mg2+ alone and drastically shortens the kinetics of germinal vesicle breakdown to 1 h 30 min to 2 h 30 min.     

Mos is not required for the initiation of meiotic maturation in Xenopus oocytes

In Xenopus oocytes, the c-mos proto-oncogene product has been proposed to act downstream of progesterone to control the entry into meiosis I, the transition from meiosis I to meiosis II, which is characterized by the absence of S phase, and the metaphase II arrest seen prior to fertilization. Here, we report that inhibition of Mos synthesis by morpholino antisense oligonucleotides does not prevent the progesterone-induced initiation of Xenopus oocyte meiotic maturation, as previously thought. Mos-depleted oocytes complete meiosis I but fail to arrest at metaphase II, entering a series of embryonic-like cell cycles accompanied by oscillations of Cdc2 activity and DNA replication. We propose that the unique and conserved role of Mos is to prevent mitotic cell cycles of the female gamete until the fertilization in Xenopus, starfish and mouse oocytes.     

U-cadherin in Xenopus oogenesis and oocyte maturation

U-cadherin is a member of the cadherin family in Xenopus that participates in interblastomere adhesion in the early embryo from the first cleavage onwards. Though a maternal pool of U-cadherin is available in the egg, it is not present on the egg membrane (Angres et al., 1991. Development 111, 829-844). To assess the origin of this unexpected distribution in the egg, the accumulation and localization of the cadherin during oogenesis and oocyte maturation were investigated. We report here that U-cadherin is present in Xenopus oocytes throughout oogenesis. It is localized at the oocyte-follicle cell contacts suggesting that it functions in the adhesion of the two cell types. When oocytes mature and the contacts to the follicle cells break, U-cadherin disappears from the oocyte surface. Evidence for a translocation of U-cadherin from the membrane to the inside of the oocyte was obtained when the fate of membrane-bound U-cadherin, which was labelled on the surface of oocytes prior to maturation, was followed through maturation. The total U-cadherin content of the oocyte increases during maturation. Metabolic labelling experiments indicate that at maturation the translation of U-cadherin is elevated well above the level that one would expect from the general increase in protein synthesis is presumably the main source of the maternal pool of U-cadherin in the egg.     

Autoregulation of Musashi1 mRNA translation during Xenopus oocyte maturation

The mRNA translational control protein, Musashi, plays a critical role in cell fate determination through sequence‐specific interactions with select target mRNAs. In proliferating stem cells, Musashi exerts repression of target mRNAs to promote cell cycle progression. During stem cell differentiation, Musashi target mRNAs are de‐repressed and translated. Recently, we have reported an obligatory requirement for Musashi to direct translational activation of target mRNAs during Xenopus oocyte meiotic cell cycle progression. Despite the importance of Musashi in cell cycle regulation, only a few target mRNAs have been fully characterized. In this study, we report the identification and characterization of a new Musashi target mRNA in Xenopus oocytes. We demonstrate that progesterone‐stimulated translational activation of the Xenopus Musashi1 mRNA is regulated through a functional Musashi binding element (MBE) in the Musashi1 mRNA 3′ untranslated region (3′ UTR). Mutational disruption of the MBE prevented translational activation of Musashi1 mRNA and its interaction with Musashi protein. Further, elimination of Musashi function through microinjection of inhibitory antisense oligonucleotides prevented progesterone‐induced polyadenylation and translation of the endogenous Musashi1 mRNA. Thus, Xenopus Musashi proteins regulate translation of the Musashi1 mRNA during oocyte maturation. Our results indicate that the hierarchy of sequential and dependent mRNA translational control programs involved in directing progression through meiosis are reinforced by an intricate series of nested, positive feedback loops, including Musashi mRNA translational autoregulation. These autoregulatory positive feedback loops serve to amplify a weak initiating signal into a robust commitment for the oocyte to progress through the cell cycle and become competent for fertilization.Mol. Reprod. Dev. 79: 553‐563, 2012. © 2012 Wiley Periodicals, Inc.     

Redundant pathways for Cdc2 activation in Xenopus oocyte: either cyclin B or Mos synthesis

Xenopus oocytes are arrested in meiotic prophase I. Progesterone induces the resumption of meiotic maturation, which requires continuous protein synthesis to bring about Cdc2 activation. The identification of the newly synthesized proteins has long been a goal. Two plausible candidates have received extensive study. The synthesis of cyclin B and of c-Mos, a kinase that activates the mitogen-activated protein kinase pathway in oocytes, is clearly upregulated by translational control in response to progesterone. Recent studies suggest that ablation of either c-Mos or cyclin B synthesis by antisense oligonucleotides does not block meiotic maturation. Here, however, we show that when both pathways are simultaneously inhibited, progesterone no longer triggers maturation; adding back either c-Mos or cyclin B restores meiotic maturation. We conclude that the specific synthesis of either B-type cyclins or c-Mos, induced by progesterone, is required to induce meiotic maturation. The two pathways seem to be functionally redundant.     

A G protein-coupled receptor kinase induces Xenopus oocyte maturation

Several recent studies have suggested that resumption of oocyte meiosis, indicated by germinal vesicle breakdown or GVBD, involves inhibition of endogenous heterotrimeric G proteins in both frogs and mice. These studies imply that a heterotrimeric G protein(s), and hence its upstream activator (a G protein-coupled receptor or GpCR), is activated in prophase oocytes and is responsible for maintaining meiosis arrest. To test the existence and function of this putative GpCR, we utilized a mammalian G-protein-coupled receptor kinase (GRK3) and beta-arrestin-2, which together are known to cause GpCR desensitization. Injection of mRNA for rat GRK3 caused hormone-independent GVBD. The kinase activity of GRK3 was essential for GVBD induction as its kinase-dead mutant (GRK3-K220R) was completely ineffective. Another GRK3 mutant (GRK3-DeltaC), which lacked the C-terminal G(betagamma)-binding domain and which was not associated with oocyte membranes, also failed to induce GVBD. Furthermore, injection of rat beta-arrestin-2 mRNA also induced hormone-independent GVBD. Several inhibitors of clathrin-mediated receptor endocytosis (the clathrin-binding domain of beta-arrestin-2, concanavalin A, and monodansyl cadaverine) significantly reduced the abilities of GRK3/beta-arrestin-2 to induce GVBD. These results support the central role of a yet-unidentified GpCR in maintaining prophase arrest in frog oocytes and provide a potential means for its molecular identification.     

Autophosphorylation of Ser66 on Xenopus Myt1 is a Prerequisite for Meiotic Inactivation of Myt1

Myt1 is a dual-specificity kinase that contributes to the regulation of the cell cycle byadding inhibitory phosphates to the cyclin-dependent kinases (Cdk/cyclins). Myt1 is found to bephosphorylated and less active in M-phase compared to interphase. Although Myt1 can bephosphorylated by several different kinases in vitro, it is not well understood how Myt1 isregulated in vivo. Additionally, the interplay between phosphorylation by other kinases andautophosphorylation has not been investigated. Since phosphorylation is an important mode ofregulation for Myt1, we have investigated the properties and physiological significance of theautophosphorylation of Myt1 from Xenopus laevis (XMyt1). Using MALDI mass spectrometrywe have identified Ser66 and Ser76 as autophosphorylation sites. Autophosphorylation isimportant for the activity of XMyt1 in intact cells, as found by comparing the timing of the cellcycle in Xenopus oocytes expressing either exogenous wild type XMyt1 or itsautophosphorylation site mutants. Specifically, S66A is significantly more potent than wild typeXMyt1 at delaying entry into meiosis and concomitantly is hypophosphorylated as evident by aloss of mobility shift. However, this cannot be accounted for by a simple increase in kinaseactivity towards Cdk/cyclins in vitro. We therefore propose that Myt1 catalyzedautophosphorylation of residue S66 is a prerequisite and/or trigger for the furtherphosphorylation and inactivation of Myt1. Thus autophosphorylation of Myt1 is a novelinhibitory mechanism that adds another layer of complexity to the phosphorylation-dependentmechanism of Myt1 regulation.     

Mos mediates the mitotic activation of p42 MAPK in Xenopus egg extracts

The ERK1/ERK2 MAP kinases (MAPKs) are transiently activated during mitosis, and MAPK activation has been implicated in the spindle assembly checkpoint and in establishing the timing of an unperturbed mitosis. The MAPK activator MEK1 is required for mitotic activation of p42 MAPK in Xenopus egg extracts; however, the identity of the kinase that activates MEK1 is unknown. Here we have partially purified a Cdc2-cyclin B-induced MEK-activating protein kinase from mitotic Xenopus egg extracts and identified it as the Mos protooncoprotein, a MAP kinase kinase kinase present at low levels in mitotic egg extracts, early embryos, and somatic cells. Immunodepletion of Mos from interphase egg extracts was found to abolish Delta90 cyclin B-Cdc2-stimulated p42 MAPK activation. In contrast, immunodepletion of Raf-1 and B-Raf, two other MEK-activating kinases present in Xenopus egg extracts, had little effect on cyclin-stimulated p42 MAPK activation. Immunodepletion of Mos also abolished the transient activation of p42 MAPK in cycling egg extracts. Taken together, these data demonstrate that Mos is responsible for the mitotic activation of the p42 MAPK pathway in Xenopus egg extracts.     

Stimulation of Xenopus laevis oocyte maturation by methyl-beta-cyclodextrin

The cholesterol-depleting drug methyl-beta-cyclodextrin (Me-beta-CD) was tested for its effects on amphibian oocyte maturation, cholesterol depletion, and low-density membrane recovery. Progesterone-induced oocyte maturation was accelerated by pretreatment of cells with 5-50 mM Me-beta-CD in a dose-dependent manner. Treatment of oocytes with 50 mM Me-beta-CD alone was sufficient to induce germinal vesicle breakdown, stimulate formation of meiotic spindles, and stimulate phosphorylation of mitogen-activated protein kinase over time courses longer than those observed after progesterone treatment. After short-term (30 min) labeling of oocytes with [(3)H]cholesterol, 30-90 min of treatment with 5-50 mM Me-beta-CD removed 50%-70% of cell- associated label, and cholesterol depletion was not observed with alpha-cyclodextrin. After long-term (20-23 h) labeling of oocytes with [(3)H]cholesterol, Me-beta-CD treatment resulted in dose- dependent cholesterol depletion in the 5-50 mM range, and 50 mM Me-beta-CD removed approximately 50% of cell-associated label after 9 h. Treatment of oocytes with 5-50 mM Me-beta-CD also decreased recovery of low-density membrane by detergent-free sucrose gradient centrifugation. These results implicate cholesterol and low-density membrane domains in the signaling mechanisms leading to germinal vesicle breakdown in amphibian oocytes.     

Modulation of O-GlcNAc glycosylation during Xenopus oocyte maturation

O-linked N-acetylglucosamine (O-GlcNAc) glycosylation is a post-translational modification, which is believed antagonises phosphorylation. We have studied the O-GlcNAc level during Xenopus oocyte meiotic resumption, taking advantage of the high synchrony of this model which is dependent upon a burst of phosphorylation. Stimulation of immature stage VI oocytes using progesterone was followed by a 4.51 +/- 0.32 fold increase in the GlcNAc content, concomitantly to an increase in phosphorylation, notably on two cytoplasmic proteins of 66 and 97 kDa. The increase of O-GlcNAc for the 97 kDa protein, which we identified as beta-catenin was partly related to its accumulation during maturation, as was demonstrated by the use of the protein synthesis inhibitor--cycloheximide. Microinjection of free GlcNAc, which inhibits O-glycosylated proteins-lectins interactions, delayed the progesterone-induced maturation without affecting the O-GlcNAc content. Our results suggest that O-GlcNAc glycosylation could regulate protein-protein interactions required for the cell cycle kinetic.     

Regulation of Greatwall kinase during Xenopus oocyte maturation

Greatwall kinase has been identified as a key element in M phase initiation and maintenance in Drosophila, Xenopus oocytes/eggs, and mammalian cells. In M phase, Greatwall phosphorylates endosulfine and related proteins that bind to and inhibit protein phosphatase 2A/B55, the principal phosphatase for Cdk-phosphorylated substrates. We show that Greatwall binds active PP2A/B55 in G2 phase oocytes but dissociates from it when progesterone-treated oocytes reach M phase. This dissociation does not require Greatwall kinase activity or phosphorylation at T748 in the presumptive T loop of the kinase. A mutant K71M Greatwall, also known as Scant in Drosophila, induces M phase in the absence of progesterone when expressed in oocytes, despite its reduced stability and elevated degradation by the proteasome. M phase induction by Scant Greatwall requires protein synthesis but is not associated with altered binding or release of PP2A/B55 as compared to wild-type Greatwall. However, in vitro studies with Greatwall proteins purified from interphase cells indicate that Scant, but not wild-type Greatwall, has low but detectable activity against endosulfine. These results demonstrate progesterone-dependent regulation of the PP2A/B55-Greatwall interaction during oocyte maturation and suggest that the cognate Scant Greatwall mutation has sufficient constitutive kinase activity to promote M phase in Xenopus oocytes.     

Aven is dynamically regulated during Xenopus oocyte maturation and is required for oocyte survival

We have analyzed the expression and function of the cell death and cell cycle regulator Aven in Xenopus. Analysis of Xenopus Aven expression in oocytes and embryos revealed a band close to the predicted molecular weight of the protein (36 kDa) in addition to two bands of higher molecular weight (46 and 49 kDa), one of which was determined to be due to phosphorylation of the protein. The protein is primarily detected in the cytoplasm of oocytes and is tightly regulated during meiotic and mitotic cell cycles. Progesterone stimulation of oocytes resulted in a rapid loss of Aven expression with the protein levels recovering before germinal vesicle breakdown (GVBD). This loss of Aven is required for the G2–M1 cell cycle transition. Aven morpholino knockdown experiments revealed that early depletion of the protein increases progesterone sensitivity and facilitates GVBD, but prolonged depletion of Aven results in caspase-3 activation and oocyte death by apoptosis. Phosphorylated Aven (46 kDa) was found to bind Bcl-x_L in oocytes, but this interaction was lost in apoptotic oocytes. Thus, Aven alters progesterone sensitivity in oocytes and is critical for oocyte survival.     

A Gbetagamma stimulated adenylyl cyclase is involved in Xenopus laevis oocyte maturation

Xenopus laevis oocyte maturation is induced by the steroid hormone progesterone through a nongenomic mechanism that implicates the inhibition of the effector system adenylyl cyclase (AC). Recently, it has been shown that the G protein betagamma heterodimer is involved in oocyte maturation arrest. Since AC is the proposed target for Gbetagamma action, we considered of importance to identify and characterize the Gbetagamma regulated AC isoform(s) that are expressed in the Xenopus oocyte. Through biochemical studies, we found that stage VI plasma membrane oocyte AC activity showed attributes of an AC2 isoform. Furthermore, exogenous Gbetagamma was capable to activate oocyte AC only in the presence of the activated form of Galphas (Galphas-GTPgammaS), which is in agreement with the Ggammabeta conditional activation reported for the mammalian AC2 and AC4 isotypes. In order to study the functional role of AC in oocyte maturation we cloned from a Xenopus oocyte cDNA library a gene encoding an AC with high identity to AC7 (xAC7). Based on this sequence, we constructed a minigene encoding the AC-Gbetagamma interacting region (xAC7pep) to block, within the oocyte, this interaction. We found that microinjection of the xAC7pep potentiated progesterone-induced maturation, as did the AC2 minigene. From these results we can conclude that a Gbetagamma-activated AC is playing an important role in Xenopus oocyte meiotic arrest in a Galphas-GTP dependent manner.