Acquisition of meiotic competence in growing mouse oocytes is controlled at both translational and posttranslational levels.

Full-grown mouse oocytes spontaneously resume meiosis in vitro when released from their follicular environment. By contrast, growing oocytes are not competent to resume meiosis; the molecular basis of meiotic competence is not known. Entry into M phase of the eukaryotic cell cycle is controlled by MPF, a catalytically active complex comprising p34cdc2 kinase and cyclin B. Incompetent oocytes contain levels of cyclin B comparable to those in competent oocytes, while their level of p34cdc2 is markedly lower; p34cdc2 accumulates abruptly at the end of oocyte growth, at the time of meiotic competence acquisition. We show here that this change in p34cdc2 concentration is not secondary to a corresponding change in the concentration of the cognate mRNA, indicating that translational control may be involved. Microinjection of translatable p34cdc2 mRNA into incompetent oocytes yielded high levels of the protein, but it did not lead to resumption of meiosis. Similarly, microinjection of cyclin B1 mRNA resulted in accumulation of the protein, but not in the acquisition of meiotic competence. By contrast, the microinjection of both p34cdc2 and cyclin B1 mRNAs in incompetent oocytes induced histone H1 and MAP kinase activation, germinal vesicle breakdown, and entry into M-phase including the translational activation of a dormant mRNA. Thus, endogenous cyclin B1 in incompetent oocytes is not available for interaction with p34cdc2, suggesting that a posttranslational event must occur to achieve meiotic competence. Microinjection of either p34cdc2 or cyclin B1 mRNAs accelerated meiotic reinitiation of okadaic acid-treated incompetent oocytes. Taken together, these results suggest that acquisition of meiotic competence by mouse oocytes is regulated at both translational and posttranslational levels.

[1]  Marc W. Kirschner,et al.  How Proteolysis Drives the Cell Cycle , 1996, Science.

[2]  W. Rom,et al.  Novel Form of p21WAF1/CIP1/SDI1 Protein in Phorbol Ester-induced G2/M Arrest* , 1996, The Journal of Biological Chemistry.

[3]  R. Schultz,et al.  Regulation of the acquisition of meiotic competence in the mouse: changes in the subcellular localization of cdc2, cyclin B1, cdc25C and wee1, and in the concentration of these proteins and their transcripts. , 1996, Journal of cell science.

[4]  M. De Felici,et al.  Mammalian oocyte growth in vitro is stimulated by soluble factor(s) produced by preantral granulosa cells and by Sertoli cells , 1996, Molecular reproduction and development.

[5]  A. Gavin,et al.  An accumulation of p34cdc2 at the end of mouse oocyte growth correlates with the acquisition of meiotic competence. , 1996, Developmental biology.

[6]  I. Vernos,et al.  Motors involved in spindle assembly and chromosome segregation. , 1996, Current opinion in cell biology.

[7]  E. Nishida,et al.  Activation mechanism and function of the MAP kinase cascade , 1995, Molecular reproduction and development.

[8]  T. Hunt,et al.  Newly synthesized protein(s) must associate with p34cdc2 to activate MAP kinase and MPF during progesterone‐induced maturation of Xenopus oocytes. , 1995, The EMBO journal.

[9]  A. Okano,et al.  Association between p34cdc2 levels and meiotic arrest in pig oocytes during early growth , 1995, Zygote.

[10]  A. N. Meyer,et al.  Requirement for phosphorylation of cyclin B1 for Xenopus oocyte maturation. , 1995, Molecular biology of the cell.

[11]  J. Fulka,et al.  Mouse oocyte maturation: meiotic checkpoints. , 1995, Experimental cell research.

[12]  H. Rime,et al.  Tyrosine phosphorylation of p34cdc2 is regulated by protein phosphatase 2A in growing immature Xenopus oocytes. , 1995, Experimental cell research.

[13]  H. Clarke,et al.  Mitogen‐activated protein (MAP) kinase during the acquisition of meiotic competence by growing oocytes of the mouse , 1995, Molecular reproduction and development.

[14]  A. Stutz,et al.  Translational Control: Awakening dormant mRNAs , 1995, Current Biology.

[15]  J. Eppig,et al.  Synthesis and accumulation of p34cdc2 and cyclin B in mouse oocytes during acquisition of competence to resume meiosis , 1995, Molecular reproduction and development.

[16]  J. Eppig,et al.  Induction of precocious germinal vesicle breakdown (GVB) by GVB-incompetent mouse oocytes: possible role of mitogen-activated protein kinases rather than p34cdc2 kinase. , 1995, Biology of reproduction.

[17]  P. Clarke,et al.  Cyclin-Dependent Kinases: CAK-handed kinase activation , 1995, Current Biology.

[18]  A. Hampl,et al.  Translational regulation of the gradual increase in histone H1 kinase activity in maturing mouse oocytes , 1995, Molecular reproduction and development.

[19]  N. Dekel,et al.  Meiotic arrest in incompetent rat oocytes is not regulated by cAMP. , 1994, Developmental biology.

[20]  J. Fulka,et al.  Sister chromatid separation and the metaphase-anaphase transition in mouse oocytes. , 1994, Developmental biology.

[21]  R. Weinberg,et al.  A cyclin associated with the CDK-activating kinase MO15 , 1994, Nature.

[22]  David O. Morgan,et al.  A novel cyclin associates with M015/CDK7 to form the CDK-activating kinase , 1994, Cell.

[23]  A. Wolffe,et al.  A role for transcription and FRGY2 in masking maternal mRNA within Xenopus oocytes , 1994, Cell.

[24]  E. Nishida,et al.  Requirement for the MAP kinase kinase/MAP kinase cascade in Xenopus oocyte maturation. , 1994, The EMBO journal.

[25]  A. Spirin Storage of messenger RNA in eukaryotes: Envelopment with protein, translational barrier at 5′ side, or conformational masking by 3′ side? , 1994, Molecular reproduction and development.

[26]  R. Moor,et al.  MPF components and meiotic competence in growing pig oocytes , 1994, Molecular reproduction and development.

[27]  J. Ruderman,et al.  Functional analysis of the P box, a domain in cyclin B required for the activation of Cdc25 , 1993, Cell.

[28]  W. Merlevede,et al.  Mitogen‐activated protein kinase (MAP kinase) activation in Xenopus oocytes: Roles of MPF and protein synthesis , 1993, Molecular reproduction and development.

[29]  A. Wolffe,et al.  Masking mRNA from translation in somatic cells. , 1993, Genes & development.

[30]  J. Labbé,et al.  The MO15 gene encodes the catalytic subunit of a protein kinase that activates cdc2 and other cyclin‐dependent kinases (CDKs) through phosphorylation of Thr161 and its homologues. , 1993, The EMBO journal.

[31]  J. Harper,et al.  CAK, the p34cdc2 activating kinase, contains a protein identical or closely related to p40MO15. , 1993, The EMBO journal.

[32]  M. Cobb,et al.  MAP kinase becomes stably activated at metaphase and is associated with microtubule-organizing centers during meiotic maturation of mouse oocytes. , 1993, Developmental biology.

[33]  T. Hunt,et al.  The cdc2‐related protein p40MO15 is the catalytic subunit of a protein kinase that can activate p33cdk2 and p34cdc2. , 1993, The EMBO journal.

[34]  T. Hunt,et al.  The c‐mos proto‐oncogene protein kinase turns on and maintains the activity of MAP kinase, but not MPF, in cell‐free extracts of Xenopus oocytes and eggs. , 1993, The EMBO journal.

[35]  Jonathan A. Cooper,et al.  Mos stimulates MAP kinase in Xenopus oocytes and activates a MAP kinase kinase in vitro , 1993, Molecular and cellular biology.

[36]  F. Aoki,et al.  Activation of mitogen-activated protein kinase during meiotic maturation in mouse oocytes. , 1993, Journal of reproduction and fertility.

[37]  A. Porras,et al.  p21ras-induced meiotic maturation of Xenopus oocytes in the absence of protein synthesis: MPF activation is preceded by activation of MAP and S6 kinases. , 1993, Oncogene.

[38]  A. Gavin,et al.  Okadaic acid and p13suc1 modulate the reinitiation of meiosis in mouse oocytes , 1992, Molecular reproduction and development.

[39]  D. Wolgemuth,et al.  Identification of a mouse B‐type cyclin which exhibits developmentally regulated expression in the germ line , 1992, Molecular reproduction and development.

[40]  J. Maller,et al.  Periodic changes in phosphorylation of the Xenopus cdc25 phosphatase regulate its activity. , 1992, Molecular biology of the cell.

[41]  J. Labbé,et al.  Dephosphorylation of cdc2 on threonine 161 is required for cdc2 kinase inactivation and normal anaphase. , 1992, The EMBO journal.

[42]  D. Belin,et al.  Transient translational silencing by reversible mRNA deadenylation , 1992, Cell.

[43]  H. Rime,et al.  Activation of p34cdc2 kinase by cyclin is negatively regulated by cyclic amp-dependent protein kinase in Xenopus oocytes. , 1992, Developmental biology.

[44]  E. Nigg,et al.  Cyclin B2 undergoes cell cycle-dependent nuclear translocation and, when expressed as a non-destructible mutant, causes mitotic arrest in HeLa cells , 1992, The Journal of cell biology.

[45]  D. Beach,et al.  Specific activation of cdc25 tyrosine phosphatases by B-type cyclins: Evidence for multiple roles of mitotic cyclins , 1991, Cell.

[46]  P. Russell,et al.  p80cdc25 mitotic inducer is the tyrosine phosphatase that activates p34cdc2 kinase in fission yeast. , 1991, The EMBO journal.

[47]  E. Nigg,et al.  Mutations of p34cdc2 phosphorylation sites induce premature mitotic events in HeLa cells: evidence for a double block to p34cdc2 kinase activation in vertebrates. , 1991, The EMBO journal.

[48]  P. Nurse,et al.  Regulatory phosphorylation of the p34cdc2 protein kinase in vertebrates. , 1991, The EMBO journal.

[49]  Marc W. Kirschner,et al.  cdc25 is a specific tyrosine phosphatase that directly activates p34cdc2 , 1991, Cell.

[50]  A. Kumagai,et al.  The cdc25 protein contains an intrinsic phosphatase activity , 1991, Cell.

[51]  T. Hunter,et al.  Human cyclins A and B1 are differentially located in the cell and undergo cell cycle-dependent nuclear transport , 1991, The Journal of cell biology.

[52]  J. Yang,et al.  MPF is activated in growing immature Xenopus oocytes in the absence of detectable tyrosine dephosphorylation of P34cdc2. , 1991, Experimental cell research.

[53]  H. Alexandre,et al.  Pleiotropic effect of okadaic acid on maturing mouse oocytes. , 1991, Development.

[54]  U. Strausfeld,et al.  Dephosphorylation and activation of a p34cdc2/cyclin B complex in vitro by human CDC25 protein , 1991, Nature.

[55]  R. Schultz,et al.  Stimulatory effect of okadaic acid, an inhibitor of protein phosphatases, on nuclear envelope breakdown and protein phosphorylation in mouse oocytes and one-cell embryos. , 1991, Developmental biology.

[56]  J. Maller,et al.  Activation of p34cdc2 kinase by cyclin A , 1991, The Journal of cell biology.

[57]  E. Nishida,et al.  In vitro effects on microtubule dynamics of purified Xenopus M phase-activated MAP kinase , 1991, Nature.

[58]  A. Murray,et al.  Cyclin is degraded by the ubiquitin pathway , 1991, Nature.

[59]  J. Motlík,et al.  Cell‐cycle aspects of growth and maturation of mammalian oocytes , 1990, Molecular reproduction and development.

[60]  Marc W. Kirschner,et al.  Cyclin activation of p34 cdc2 , 1990, Cell.

[61]  G. Schatten,et al.  Microinjected centromere [corrected] kinetochore antibodies interfere with chromosome movement in meiotic and mitotic mouse oocytes [published erratum appears in J Cell Biol 1990 Dec;111(6 Pt 1):following 2800] , 1990, The Journal of cell biology.

[62]  H. Rime,et al.  Protein phosphatases are involved in the in vivo activation of histone H1 kinase in mouse oocyte. , 1990, Developmental Biology.

[63]  M. Ishiura,et al.  The starfish egg mRNA responsible for meiosis reinitiation encodes cyclin. , 1990, Developmental biology.

[64]  A. Johnson,et al.  In vivo regulation of MPF in Xenopus oocytes. , 1990, Development.

[65]  P. Nurse Universal control mechanism regulating onset of M-phase , 1990, Nature.

[66]  M. Dorée Control of M-phase by maturation-promoting factor. , 1990, Current opinion in cell biology.

[67]  P. Cohen,et al.  Okadaic acid: a new probe for the study of cellular regulation. , 1990, Trends in biochemical sciences.

[68]  R. Rickles,et al.  Regulated polyadenylation controls mRNA translation during meiotic maturation of mouse oocytes. , 1989, Genes & development.

[69]  G. Woude,et al.  The c-mos proto-oncogene product is a cytostatic factor responsible for meiotic arrest in vertebrate eggs , 1989, Nature.

[70]  Kathleen L. Gould,et al.  Tyrosine phosphorylation of the fission yeast cdc2+ protein kinase regulates entry into mitosis , 1989, Nature.

[71]  J. Ruderman,et al.  The role of cyclin B in meiosis I , 1989, The Journal of cell biology.

[72]  T. Hunt,et al.  Maturation promoting factor, cyclin and the control of M-phase. , 1989, Current opinion in cell biology.

[73]  A. Takai,et al.  Inhibitory effect of a marine-sponge toxin, okadaic acid, on protein phosphatases. Specificity and kinetics. , 1988, The Biochemical journal.

[74]  T. Kishimoto,et al.  Regulation of meiotic metaphase by a cytoplasmic maturation-promoting factor during mouse oocyte maturation. , 1988, Developmental biology.

[75]  D. Belin,et al.  Meiotic maturation of mouse oocytes triggers the translation and polyadenylation of dormant tissue-type plasminogen activator mRNA. , 1987, Genes & development.

[76]  T. Hunt,et al.  Molecular cloning and characterization of the mRNA for cyclin from sea urchin eggs. , 1987, The EMBO journal.

[77]  Paul Russell,et al.  Negative regulation of mitosis by wee1 +, a gene encoding a protein kinase homolog , 1987, Cell.

[78]  M. Taylor,et al.  Induction of maturation in small Xenopus laevis oocytes. , 1987, Developmental biology.

[79]  G. Borisy,et al.  Chromosomes move poleward in anaphase along stationary microtubules that coordinately disassemble from their kinetochore ends , 1987, The Journal of cell biology.

[80]  J. Ruderman,et al.  The clam embryo protein cyclin A induces entry into M phase and the resumption of meiosis in Xenopus oocytes , 1986, Cell.

[81]  Paul Russell,et al.  cdc25 + functions as an inducer in the mitotic control of fission yeast , 1986, Cell.

[82]  D. Belin,et al.  Plasminogen activator in mouse and rat oocytes: Induction during meiotic maturation , 1985, Cell.

[83]  M. Cyert,et al.  Active maturation-promoting factor is present in mature mouse oocytes , 1985, The Journal of cell biology.

[84]  D. Belin,et al.  Concomitant secretion of prourokinase and of a plasminogen activator- specific inhibitor by cultured human monocytes-macrophages , 1984, The Journal of experimental medicine.

[85]  F. Palombi,et al.  Early programming of maturation competence in mouse oogenesis. , 1984, Developmental biology.

[86]  R. Bachvarova Synthesis, turnover, and stability of heterogeneous RNA in growing mouse oocytes. , 1981, Developmental biology.

[87]  S. Glasser,et al.  Cellular and Molecular Aspects of Implantation , 1981 .

[88]  P. Wassarman,et al.  Oocyte development in the mouse: An ultrastructural comparison of oocytes isolated at various stages of growth and meiotic competence , 1978, Journal of morphology.

[89]  H. Bałakier Induction of maturation in small oocytes from sexually immature mice by fusion with meiotic or mitotic cells. , 1978, Experimental cell research.

[90]  P. Wassarman,et al.  Biochemical studies of mammalian oogenesis: Protein synthesis during oocyte growth and meiotic maturation in the mouse. , 1977, Journal of cell science.

[91]  P. Wassarman,et al.  Relationship between growth and meiotic maturation of the mouse oocyte. , 1976, Developmental biology.

[92]  K. Drury,et al.  Effects of cycloheximide on the “autocatalytic” nature of the maturation promoting factor (MPF) in oocytes of Xenopus laevis , 1975, Cell.

[93]  G. Erickson,et al.  In vitro maturation of mouse oocytes isolated from late, middle, and pre-antral graafian follicles. , 1974, The Journal of experimental zoology.

[94]  J. Reynhout,et al.  Studies on the appearance and nature of a maturation-inducing factor in the cytoplasm of amphibian oocytes exposed to progesterone. , 1974, Developmental biology.

[95]  J. Biggers,et al.  Inhibitory effect of dibutyryl cAMP on mouse oocyte maturation in vitro. , 1974, The Journal of experimental zoology.

[96]  K. Szybek In-vitro maturation of oocytes from sexually immature mice. , 1972, The Journal of endocrinology.

[97]  U. K. Laemmli,et al.  Cleavage of Structural Proteins during the Assembly of the Head of Bacteriophage T4 , 1970, Nature.

[98]  G. Pincus,et al.  THE COMPARATIVE BEHAVIOR OF MAMMALIAN EGGS IN VIVO AND IN VITRO , 1935, The Journal of experimental medicine.

[99]  E. Joly Preparation of plasmid DNA using alkaline lysis. , 1996, Methods in molecular biology.

[100]  D. Belin The RNase protection assay. , 1996, Methods in molecular biology.

[101]  D. Belin The use of riboprobes for the analysis of gene expression. , 1994, Methods in molecular biology.

[102]  A. Gavin,et al.  Histone H1 kinase activity, germinal vesicle breakdown and M phase entry in mouse oocytes. , 1994, Journal of cell science.

[103]  K. Wigglesworth,et al.  Acquisition of meiotic competence by denuded mouse oocytes: participation of somatic-cell product(s) and cAMP. , 1994, Developmental biology.

[104]  A. Gavin,et al.  Induction of M-phase entry of prophase-blocked mouse oocytes through microinjection of okadaic acid, a specific phosphatase inhibitor. , 1991, Experimental cell research.

[105]  N. Spurr,et al.  Cloning of the mouse homologue of the yeast cell cycle control gene cdc2. , 1990, DNA sequence : the journal of DNA sequencing and mapping.

[106]  K. Weber,et al.  Immunofluorescence and immunocytochemical procedures with affinity purified antibodies: tubulin-containing structures. , 1982, Methods in cell biology.

[107]  J. Blerkom Intrinsic and Extrinsic Patterns of Molecular Differentiation during Oogenesis, Embryogenesis, and Organogenesis in Mammals , 1981 .