Involvement of cAMP-dependent protein kinase and protein phosphorylation in regulation of mouse oocyte maturation

We report the results of experiments which support the hypothesis that, in mouse oocytes, a decrease in intraoocyte cyclic AMP (cAMP) initiates meiotic maturation; oocytes microinjected with cyclic nucleotide phosphodiesterase (PDE) underwent germinal vesicle breakdown (GVBD) in the presence of 3-isobutyl-1-methylxanthine (IBMX), which inhibited GVBD both in oocytes not injected with PDE and in oocytes injected with heat-inactivated PDE. Cyclic AMP-dependent protein kinase (PK) has been proposed to mediate maintenance of meiotic arrest by cAMP. In support of this hypothesis is the observation that 2'-deoxy cAMP, which does not activate PK, did not maintain meiotic arrest as did cAMP; this result was obtained both by microinjection of these compounds and by incubating oocytes in the presence of their membrane-permeable N6-monobutyryl derivatives. Furthermore, microinjection into oocytes of the heat-stable inhibitor of PK, PKI, induced GVBD in the presence of either dibutyryl cAMP (dbcAMP) or IBMX. Meiotic arrest was maintained in the absence of dbcAMP or IBMX, however, by microinjected catalytic subunit of PK, but not by catalytic subunit coinjected with PKI. In addition, specific changes in oocyte phosphoproteins that preceded resumption of meiosis were induced, in the presence of dbcAMP, by microinjected PKI; these changes were also tightly coupled with commitment of oocytes to resume meiosis. These results are discussed in terms of our model for regulation of meiotic arrest and maturation.     

Nongenomic steroid-triggered oocyte maturation: Of mice and frogs

Luteinizing hormone (LH) mediates many important processes in ovarian follicles, including cumulus cell expansion, changes in gap junction expression and activity, sterol and steroid production, and the release of paracrine signaling molecules. All of these functions work together to trigger oocyte maturation (meiotic progression) and subsequent ovulation. Many laboratories are interested in better understanding both the extra-oocyte follicular processes that trigger oocyte maturation, as well as the intra-oocyte molecules and signals that regulate meiosis. Multiple model systems have been used to study LH-effects in the ovary, including fish, frogs, mice, rats, pigs, and primates. Here we provide a brief summary of oocyte maturation, focusing primarily on steroid-triggered meiotic progression in frogs and mice. Furthermore, we present new studies that implicate classical steroid receptors rather than alternative non-classical membrane steroid receptors as the primary regulators of steroid-mediated oocyte maturation in both of these model systems.     

Involvement of protein kinase C in the regulation of oocyte maturation in amphibians (Rana dybowskii)

Ovarian oocytes of Rana dybowskii, isolated early in the hibernation period (late autumn), failed to mature, i.e., germinal vesicle breakdown (GVBD), in response to progesterone during in vitro follicle culture. Oocytes collected during the middle hibernation period matured in response to progesterone, whereas those collected late during the hibernation period (close to the breeding season) underwent spontaneous maturation without added hormone (Kwon et al., '89). The maturational response (GVBD) of oocytes, collected at the three stages of hibernation, to protein kinase C (PKC) activation was investigated and compared to that of progesterone stimulation. A phorbol ester, phorbol 12-myristate 13-acetate (TPA) was used for PKC activation. TPA addition to cultured follicles collected during the early or middle period of hibernation induced oocyte GVBD. The incidence of maturation (% GVBD) induced by TPA varied markedly between animals. TPA (10 microM) induced oocyte maturation in the presence or absence of follicle cells. The time course of the TPA-induced maturation was similar to that of progesterone-stimulated maturation (ED50, 7-9 h). TPA also accelerated the onset of maturation of the follicular oocytes exhibiting spontaneous in vitro maturation. Both TPA- and progesterone-stimulated maturation was blocked by treatment with cycloheximide (1 microgram/2 ml), forskolin (9 microM) (an adenylate cyclase stimulator), and verapamil (0.27 mM) (a calcium transport blocker). Treatment of oocytes with a calmodulin antagonist N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7) (100 microM) or a PKC inactivator 1-(5-isoquinolinylsulfonyl)-2-methyl-piperazine (H-7) (50 microM) likewise suppressed TPA- or progesterone-induced maturation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Involvement of GABAA receptor in Bufo arenarum oocyte maturation

Amphibian oocytes meiotic arrest is released under the stimulus of progesterone; this hormone interacts with the oocyte surface and starts a cascade of events leading to the activation of a cytoplasmic maturation promoting factor (MPF) that induces germinal vesicle breakdown (GVBD), chromosome condensation and extrusion of the first polar body.The aim of this work was to determine whether the activation of a GABAA receptor is able to induce GVBD in fully grown denuded oocytes of Bufo arenarum and to analyse its possible participation in progesterone-induced maturation. We also evaluated the role of purines and phospholipids in the maturation process induced by a GABAA receptor agonist such as muscimol.Our results indicated that the activation of the GABAA receptor by muscimol induces maturation in a dose- and time-dependent manner and that this activation is a genuine maturation that enables oocytes to form pronuclei. Assays with a receptor antagonist, picrotoxine, showed that the maturation induced by muscimol was inhibited. Treatment with picrotoxine, however, shows that the participation of GABAA receptor in progesterone-induced maturation is not significant.In addition, our results indicate that high intracellular levels of purines obtained by the use of db-AMPc and theophylline or the inhibition of the phosphatidylinositol 4,5-bisphosphate (PIP2 hydrolysis by neomycin and PIP2 turn over by LiCl, respectively, inhibited the maturation induced by muscimol. Treatment with H-7 indicated, however, that PKC activation is not necessary for GVBD induced by the GABAA receptor agonist. Results suggest that the transduction pathway used by the GABAA receptor to induce maturation is different from those used by progesterone.     

Involvement of Xenopus Pumilio in the translational regulation that is specific to cyclin B1 mRNA during oocyte maturation

Protein synthesis of cyclin B by translational activation of the dormant mRNA stored in oocytes is required for normal progression of maturation. In this study, we investigated the involvement of Xenopus Pumilio (XPum), a cyclin B1 mRNA-binding protein, in the mRNA-specific translational activation. XPum exhibits high homology to mammalian counterparts, with amino acid identity close to 90%, even if the conserved RNA-binding domain is excluded. XPum is bound to cytoplasmic polyadenylation element (CPE)-binding protein (CPEB) through the RNA-binding domain but not to its phosphorylated form in mature oocytes. In addition to the CPE, the XPum-binding sequence of cyclin B1 mRNA acts as a cis-element for translational repression. Injection of anti-XPum antibody accelerated oocyte maturation and synthesis of cyclin B1, and, conversely, over-expression of XPum retarded oocyte maturation and translation of cyclin B1 mRNA, which was accompanied by inhibition of poly(A) tail elongation. The injection of antibody and the over-expression of XPum, however, had no effect on translation of Mos mRNA, which also contains the CPE. These findings provide the first evidence that XPum is a translational repressor specific to cyclin B1 in vertebrates. We propose that in cooperation with the CPEB-maskin complex, the master regulator common to the CPE-containing mRNAs, XPum acts as a specific regulator that determines the timing of translational activation of cyclin B1 mRNA by its release from phosphorylated CPEB during oocyte maturation.     

Involvement of mitogen-activated protein kinase cascade during oocyte maturation and fertilization in mammals

Mitogen-activated protein kinase (MAPK) is a family of Ser/Thr protein kinases that are widely distributed in eukaryotic cells. Studies in the last decade revealed that MAPK cascade plays pivotal roles in regulating the meiotic cell cycle progression of oocytes. In mammalian species, activation of MAPK in cumulus cells is necessary for gonadotropin-induced meiotic resumption of oocytes, while MAPK activation is not required for spontaneous meiotic resumption. After germinal vesicle breakdown (GVBD), MAPK is involved in the regulation of microtubule organization and meiotic spindle assembly. The activation of this kinase is essential for the maintenance of metaphase II arrest, while its inactivation is a prerequisite for pronuclear formation after fertilization or parthenogenetic activation. MAPK cascade interacts extensively with other protein kinases such as maturation-promoting factor, protein kinase A, protein kinase C, and calmodulin-dependent protein kinase II, as well as with protein phosphatases in oocyte meiotic cell cycle regulation. The cross talk between MAPK cascade and other protein kinases is discussed. The review also addresses unsolved problems and discusses future directions.     

Studies of the role of steroid hormone in the regulation of oocyte maturation in cattle

Background  

The objective of this study was to investigate whether the steroid hormone(s) secreted from cumulus-oocyte complexes (COCs) is a prerequisite for bovine oocyte maturation and cumulus expansion using aminoglutethimide (AGT), a P450 cholesterol side-chain cleavage inhibitor.     

Involvement of microtubules and microfilaments in the control of the nuclear movement during maturation of mouse oocyte

We confirm that the centrifugal migration of the chromosomes in maturing mouse oocytes depends on a microfilament-mediated process. We investigated the role of the cytoskeleton in the germinal vesicle (GV) behavior of oocytes prevented from resuming meiosis by either activators of protein kinase A or activators of protein kinase C. A time-lapse microcinematography study demonstrates that GV immobilization by isobutylmethylxanthine (IBMX) is overcome by colcemid (COL), nocodazole (NOC), and taxol and that cytochalasin D (CCD) reversibly immobilizes the GV of oocytes treated with either IBMX + COL (or NOC) or 12-O-tetradecanoylphorbol-13-acetate (TPA), an activator of protein kinase C, known to allow a programmed GV cortical translocation. An immunofluorescence analysis shows that the disorganization of a perinuclear microtubule network is the very first cytological clue of maturation. IBMX promotes its persistence while NOC, COL, and taxol induce its immediate disappearance. It is concluded that elements of the cytoplasmic microtubular complex (CMTC) are passively involved in the control of the setting up of a "centrifugal displacement property" (CDP) by counteracting a motive force provided by the microfilament cytoskeleton. Finally, TPA induces a clearcut reorganization instead of a total disorganization of the CMTC. This reorganization is, however, sufficient to allow the microfilaments to drive the GV displacement.     

A receptor linked to a Gi-family G-protein functions in initiating oocyte maturation in starfish but not frogs

The stimulation of oocyte maturation by 1-methyladenine in starfish, and by a steroid in frogs, has been proposed to involve G-protein-coupled receptors. To examine whether activation of receptors linked to G(i) or G(z) was sufficient to cause oocyte maturation, we expressed mammalian G(i)- and G(z)-linked receptors in starfish and frog oocytes. Application of the corresponding agonists caused meiosis to resume in the starfish but not the frog oocytes. We confirmed that the receptors were effectively expressed in the frog oocytes by using a chimeric G-protein, G(qi), that converts input from G(i)- and G(z)-linked receptors to a G(q) output and results in a contraction of the oocyte's pigment. These results argue against G(i) or G(z) functioning to cause maturation in frog oocytes. Consistently, maturation-inducing steroids did not cause pigment contraction in frog oocytes expressing G(qi), and G(z) protein was not detectable in frog oocytes. For starfish oocytes, however, our results support the conclusion that G(i) functions in 1-methyladenine signaling and suggest the possibility of using frog oocyte pigment contraction as an assay to identify the 1-methyladenine receptor. To test this concept, we coexpressed G(qi) and a starfish adenosine receptor in frog oocytes and showed that applying adenosine caused pigment contraction.     

Intrafollicular control of oocyte maturation in the PIG

Summary The mammalian oocyte becomes arrested at the diplotene stage of the first meiotic division during prenatal or early postnatal life. It remains arrested in meiosis until shortly before ovulation when the surge of gonadotropin induces resumption and completion of meiosis to the metaphase II stage. When oocytes are harvested from medium-sized or large follicles of pig and other species and cultured, they resume meiosis spontaneously indicating that the follicles exert an inhibitory influence on meiosis. To analyze the control of meiosis by follicular components, culture of isolated pig oocytes in the presence of follicular cells or follicular fluid (FF1) has been used as a model in this laboratory. An oocyte maturation inhibitor (OMI) has been isolated and partially purified by ultrafiltration and gel chromatography of FF1 and shown to be a polypetide with a molecular weight in the order of 2000 daltons. Physiological characterization has shown that the effect of OMI in vitro is reversible and that it can be overcome by luteinizing hormone (LH). The action of OMI requires the presence of cumulus cells surrounding the oocyte since it was found that denuded oocytes, stripped of cumulus cells, do not respond to OMI. Furthermore, when cumulus-enclosed oocytes were cultured, OMI inhibited the differentiation of the cumulus cells in terms of morphology and progesterone secretion in a dose-related manner. The inhibition of cumulus differentiation by OMI was reversible and could be overcome by LH. The results indicate that the effect of partially purified OMI upon meiosis may be mediated by the cumulus cells. Presented in the formal symposium on Sexual Differentiation in Vitro and in Vivo at the 29th Annual Meeting of the Tissue Culture Association, Denver, Colorado, June 4–8, 1978. This study was supported by Grants 760–0530 from the Ford Foundation (to C.P.C.), and Grant B78-14F-5158-01 from the Swedish Medical Research Council (to T.H.).     

Ecdysteroid regulation of ovarian growth and oocyte maturation in the red flour beetle,Tribolium castaneum

Previous studies from our laboratory showed the involvement of juvenile hormone (JH) and ecdysteroid signaling in the regulation of female reproduction in the red flour beetle, Tribolium castaneum. JH regulates vitellogenin (Vg) synthesis in the fat body but the role of ecdysteroid signaling is not known. Here, we report on ecdysteroid regulation of ovarian growth and oocyte maturation. Microarray analysis of RNA isolated from ovaries showed the up-regulation of several genes coding for proteins involved in ecdysteroid signaling on the 4th day after female adult eclosion. The functional analyses of genes coding for proteins involved in ecdysteroid and JH signaling pathways by RNA interference (RNAi) revealed that ecdysteroids but not JH regulate ovarian growth and primary oocyte maturation. Ultrastructural studies showed the temporal sequences of key events in oogenesis including the development of primary oocytes, the differentiation and development of follicle epithelial cells, and the formation of intercellular spaces to facilitate uptake of Vg protein. RNAi studies showed that ecdysone receptor (EcR) and ultraspiracle (USP) are required for the ovarian growth, primary oocyte maturation and the growth and migration of the follicle cells. These studies suggest important roles for ecdysteroids in the regulation of oocyte maturation in the beetle ovaries.     

Regulation of amphibian oocyte maturation

Xenopus oocyte maturation is a model system for studying the control of cell proliferation and the regulation of the cell cycle. Addition of progesterone or insulin to oocytes releases a G2 block and stimulates progression through meiosis to an unfertilized egg. The release of the G2 block is a consequence of a decrease in cAMP mediated entirely or in part by an inhibition of adenylate cyclase. The mechanism of cyclase inhibition involves a membrane steroid receptor controlling the rate of guanine nucleotide exchange. Subsequent events include an increase in intracellular pH and the phosphorylation of ribosomal protein S6. The latter event may play a role in translational control of maturation. Late events in maturation involve the appearance of the maturation-promoting factor (MPF), a cytoplasmic protein responsible for causing nuclear envelope breakdown, chromosome condensation, and spindle formation. MPF oscillates in meiotic and mitotic cell cycles. The events caused by MPF can now be obtained in crude extracts with retention of cell cycle control by calcium, providing a framework for rapid progress in characterizing MPF and its regulation.     

Intramitochondrial transformations during oocyte maturation in the mouse

An electron microscope study of oocyte maturation in the mouse revealed that some mitochondria undergo gradual transformation in their ultrastructural appearance. In very young oocytes these mitochondria were already found to contain vacuoles, one in each such organelle. In somewhat older oocytes more mitochondria displayed vacuoles which generally appeared to be getting larger. These intramitochondrial vacuoles were found to be essentially optically empty structures surrounded by a single membrane. In favorable sections someof the developing vacuoles had a bottle-shaped appearance, the constricted end of which was attached to the inner limiting membrane of the mitochondrion. With further maturation of the oocytes vacuoles having a pear-shaped appearance became evident. An hypothesis was presented outlining the mode of formation of these vacuoles by expansion of the individual cristae. Intramitochondrial transformations occuring during both oogenesis and spermatogenesis in mammals were reviewed.     

Ultrastructure of in-vitro oocyte maturation in cattle

Cumulus-oocyte complexes were collected from cows at an abattoir by aspiration from small (1-6 mm) antral follicles. After different periods of culture the complexes were processed for electron microscopy. Cumulus expansion occurred at 12-18 h of culture and concomitantly enlargement of cumulus cell projections in the perivitelline space was seen. At 48 h the innermost cumulus cells flattened and adhered tightly to the zona pellucida. In the oocyte the following changes occurred: at 0-3 h of culture the perivitelline space developed; at 3-12 h disconnection of the junctions between cumulus cell projections and the oolemma, and the concomitant breakdown of the nucleus was observed; at 12-18 h the mitochondria moved from a peripheral location to a more even spatial distribution and the Golgi complexes decreased in size; at approximately 18 h the smooth endoplasmic reticulum formed large aggregates surrounded by mitochondria; at 18-21 h the first polar body was abstricted; at 24-40 h the cortical granules spread; at 30-40 h the polar body degenerated in some specimens; at 40-48 h the perivitelline space decreased in size; and at 48 h one oocyte was in the process of fragmentation. It is concluded that nuclear and cytoplasmic oocyte maturation is simulated in vitro. However, certain deviations were noticed compared to in-vivo maturation.