Three calcium-sensitive genes, fus, brd3 and wdr5, are highly expressed in neural and renal territories during amphibian development.

Numerous Ca(2+) signaling events have been associated with early development of vertebrate embryo, from fertilization to organogenesis. In Xenopus laevis, Ca(2+) signals are key regulators in the earliest steps of the nervous system development. If neural determination is one of the best-characterized examples of the role of Ca(2+) during embryogenesis, increasing literature supports a determining role of organogenesis and differentiation. In blastula the cells of the presumptive ectoderm (animal caps) are pluripotent and can be induced toward neural fate with an intracellular increase of free Ca(2+) triggered by caffeine. To identify genes that are transcribed early upon Ca(2+) stimuli and involved in neural determination, we have constructed a subtractive cDNA library between neuralized and non-neuralized animal caps. Here we present the expression pattern of three new Ca(2+)-sensitive genes: fus (fused in sarcoma), brd3 (bromodomain containing 3) and wdr5 (WD repeat domain 5) as they all represent potential regulators of the transcriptional machinery. Using in situ hybridization we illustrated the spatial expression pattern of fus, brd3 and wdr5 during early developmental stages of Xenopus embryos. Strikingly, their domains of expression are not restricted to neural territories. They all share a specific expression throughout renal organogenesis which has been found to rely also on Ca(2+) signaling. This therefore highlights the key function of Ca(2+) target genes in specific territories during early development. We propose that Ca(2+) signaling through modulation of fus, brd3 and wdr5 expressions can control the transcription machinery to achieve proper embryogenesis. This article is part of a Special Issue entitled: 12th European Symposium on Calcium.

Meiosis reinitiation as a model system for the study of cell division and cell differentiation.

In this paper, we review our findings concerning the control of meiosis reinitiation in starfish oocytes and discuss recent advances that lead to characterization of the maturation promoting factor (MPF) responsible for G2-M transition. It is now agreed that appearance of this factor, which triggers nuclear envelope breakdown, chromosome condensation and metaphase spindle formation, corresponds to the activation of a M-phase specific H1-kinase. MPF has been shown to be constituted of equimolar amounts of a 34 kDa catalytic subunit protein homologous to the yeast cdc2/CDC28 gene product and a cyclin protein homologous to the yeast cdc13 gene product. "In vivo" and "in vitro" studies based on the use of inhibitors of protein synthesis, protein kinases, phosphoprotein phosphatases and proteases lead to a better understanding of the complex series of events which regulate activation and inactivation of MPF. In the unfertilized metaphase 2-arrested vertebrate oocyte, it has also been shown that stabilization of MPF depends on the kinase activity of the c-mos protooncogene. This review attempts to illustrate how the significant progress made in the understanding of the regulation of cell cycle transverse directly resulted from the convergence of observations in multidisciplinary studies in yeast genetics, development and oncogenesis. It also offers a model for considering the highly integrated events which, starting at the level of the plasma membrane, may eventually result in early cell differentiation.

The release from metaphase arrest in blue mussel oocytes.

In Mytilus edulis, shed oocytes are arrested at metaphase I of meiosis until fertilization. We previously suggested (Dubé and Dufresne, J. Exp. Zool. 256:323-332, 1990) that such a metaphase arrest depends upon a continuous synthesis of short-lived proteins, the destruction of which is sufficient to induce meiosis resumption. We further investigated the mechanism of metaphase release in blue mussel oocytes as triggered either by fertilization or by inhibition of protein synthesis (emetine) or phosphorylation (6-dimethylaminopurine, 6-DMAP). Treatment of unfertilized oocytes (UF) with emetine induces completion of the first meiotic cycle including extrusion of the polar body, followed by chromosome decondensation and by the formation of large membrane-bound nuclei, as visualized by Hoechst staining and transmission electron microscopy (TEM). Inhibition of protein phosphorylation with 6-DMAP induces directly chromosome decondensation and the formation of multiple nuclei surrounded by nuclear membrane. These interphasic nuclei exhibit continuous 3H-thymidine incorporation. p13 precipitation of p34 and associated proteins reveals "putative" cyclins in UF, no longer detected after metaphase/anaphase transition due to fertilization or emetine treatment. In the presence of 6-DMAP, new migrating forms are observed. The phosphorylated p34cdc2 homolog becomes dephosphorylated after fertilization or emetine treatment, whereas 6-DMAP induces its phosphorylation on tyrosine. Histone H1 kinase activity is reduced after these treatments, compared to the UF sample. Our results suggest that the metaphase/anaphase transition triggered by fertilization in blue mussel oocytes is induced by the rapid destruction of a set of continuously synthesized proteins accompanied by decreased histone H1 kinase activity. These events can be mimicked by inhibiting protein synthesis. Inhibition of protein phosphorylation would drive the cell to interphase without commitment to meiosis I.

Ligand-blotting visualization of the LDL receptor in plasma membranes and in two classes of coated vesicles from adrenocortical cells.

Two populations of coated vesicles, different in size, have been isolated from the bovine adrenal cortex. The enrichment of the LDL receptor from the plasma membrane to the large coated vesicles and then to the small ones was evidenced by ligand-blotting ELISA assays. The LDL receptor has been characterized as a 130-kDa proteic component which retains the binding specificity and structural features in plasma membranes as well as in the two classes of coated vesicles.

Urea-Induced Meiosis Reinitiation in Oocytes of the Starfish, Marthasterias glacialis: (intracellular calcium/maturation promoting factor/polyethylene glycol-induced cell fusion/protein phosphorylation/starfish oocyte maturation).

In the absence of hormone stimulation, prophase-blocked oocytes of Marthasterias glacialis have been induced to undergo meiosis reinitiation up to female pronucleus formation by pulse incubation in isoosmotic urea-sea water solutions. Even when this procedure was not effective all along the breeding season, it could trigger full maturation when applied to so-called "incompetent oocytes" that did not complete maturation following microinjection-induced mixing of their nucleoplasm and cytoplasm. 32 P phosphate incorporation into proteins and cell fusion experiments demonstrate that this treatment produces an increased protein phosphorylation which appears tightly associated with the production of M-phase promoting factor (MPF). Instead, when oocytes are maintained in the inducing medium, dephosphorylation soon occurs and MPF is no longer present to support meiosis. Under these conditions, the GV-disrupted oocytes present a permanent nucleolus and do not form a meiotic spindle. The same cytological aspect was also obtained when the oocytes were treated in the presence of 90 µM emetine or 150 µM of the intracellular chelator Quin 2-AM. These data suggest that urea-induced maturation may involve an intracellular Ca2+ shift which would be required to activate both MPF precursor molecules and the resting female centers which stand in the animal cortex outside the nucleus and give rise to the poles of the first maturation spindle. They also show that nuclear disruption alone, without protein phosphorylation, cannot trigger meiosis reinitiation of incompetent oocytes.

6-Dimethylaminopurine blocks starfish oocyte maturation by inhibiting a relevant protein kinase activity.

The puromycin analog N6,N6-dimethyladenine (6-dimethylaminopurine or 6-DMAP) was found to inhibit meiosis reinitiation in starfish oocytes stimulated by the natural hormone 1-methyladenine. Increasing concentrations of this agent delayed and eventually blocked germinal vesicle breakdown. They were found to be effective even when applied during the hormone-independent period, after the oocytes had been already committed to reinitiate meiosis. 6-DMAP mimics most of the effects of emetine since it induces protein dephosphorylation, inhibits polar body formation, and promotes the precocious appearance of resting nuclei. However, unlike emetine, 6-DMAP does not affect protein synthesis. The effect of this agent cannot be accounted for by a stimulation of the protease or phosphoprotein phosphatase activities since the rate and extent of protein dephosphorylation do not increase in its presence. Data from in vivo and in vitro endogenous protein phosphorylation experiments suggest rather that 6-DMAP may directly or indirectly affect the activity of a relevant c-AMP and Ca2+-independent protein kinase which is stimulated after hormone addition and seems to support starfish oocyte maturation.

Metabolic cooperation following fusion of starfish ootid and primary oocyte restores meiotic-phase-promoting activity.

In the starfish Marthasterias glacialis, polyethylene glycol (PEG) homologous fused pairs consisting of two immature oocytes, blocked at the germinal vesicle stage, or two ootids, blocked at the female pronucleus stage, remain arrested at these specific stages, unless they are stimulated by the hormone 1-methyladenine. In contrast, heterologous pairs develop up to female pronucleus formation in the immature partner, indicating that maturation-promoting factor was formed under these conditions. Kinetics for this process, reconstitution of the nuclear envelopes after first polar body extrusion, and delaying effect of emetine argue for the existence of a true metabolic cooperation process requiring complementary factors present in each partner. The effect of inhibitors that penetrate the plasma membrane points to the possible involvement of endogenous proteases that may activate latent or neosynthesized maturation-promoting factor precursor and/or protein kinases.

DNA replication initiation by 6-DMAP treatment in maturing oocytes and dividing embryos from marine invertebrates.

6-dimethylaminopurine (6-DMAP), a potent protein kinase inhibitor, drives most cells into an interphasic stage. Experiments were undertaken with oocytes from three marine invertebrate species, i.e., Mytilus edulis, Spisula solidissima, and Strongylocentrotus droebachiensis, wherein oocytes were arrested at different phases of meiosis. 6-DMAP induced a continuous DNA synthesis in meiotic cells, whereas it allowed a single round of DNA replication in treated mitotic cells, regardless of species considered. The effects of 6-DMAP were accompanied in all cases by rephosphorylation on tyrosine of the p34cdc2 homolog, the M-phase promoting factor (MPF) catalytic subunit. The fact that 6-DMAP overcomes the inhibitory control of replication during meiosis suggests that this process depends upon protein phosphorylation, while DNA synthesis regulation in mitotic cells relies on 6-DMAP-insensitive events.

A requirement for protein phosphorylation in regulating the meiotic and mitotic cell cycles in echinoderms.

Populations of hormone-stimulated starfish oocytes and fertilized sea urchin eggs undergo synchronous meiotic and mitotic divisions. We have studied the requirement for protein phosphorylation during these events by testing the effects of 6-dimethylaminopurine (6-DMAP) upon the incorporation of [32P]orthophosphate. It was found that 6-DMAP blocked meiosis reinitiation and early cleavage and simultaneously inhibited protein phosphorylation, without changing the rate of [35S]methionine incorporation or pattern of protein synthesis. The protein, cyclin (54 kDa in starfish and 57 kDa in sea urchin), continues to be synthesized in the presence of 6-DMAP. This protein is destroyed at first and second cell cycles when 6-DMAP is added 30 min following fertilization but not when this drug is present before fertilization. Thus, cyclin breakdown does not depend on the completion of the nuclear events of M-phase, and its time of breakdown is set at an early step between fertilization and first cleavage. Using tubulin immunostaining, we found that 6-DMAP did not affect the cortical microtubules and resting female centrioles of prophase-arrested starfish oocytes, whereas it induced a precocious disappearance of spindle fibers when applied to hormone-stimulated oocytes. While an early addition of 6-DMAP precluded nuclear breakdown and spindle formation in both systems, a late treatment always allowed chromosome separation and centriole separation. Under these conditions pericentriolar tubulin persisted and could organize new spindles after the inhibitor was removed. It is suggested that (1) the assembly of cortical and centriolar-associated microtubules is not controlled by the same factors as spindle-associated tubulin; (2) specific proteins which are required for the cell to enter the following M-phase can become operative only via a process depending upon protein phosphorylation; (3) microtubule-associated kinases may play an important role in MPF function and spindle dynamics.

6-Dimethylaminopurine (6-DMAP), a reversible inhibitor of the transition to metaphase during the first meiotic cell division of the mouse oocyte.

The first meiotic cell division (meiotic maturation) of dictyate stage mouse oocytes removed from the follicle resumes spontaneously in vitro. We used the puromycin analog 6-dimethylaminopurine (6-DMAP) to test the respective roles of protein synthesis and protein phosphorylation in driving this process. While protein synthesis inhibitors do not block meiosis resumption, 6-DMAP was found to inhibit germinal vesicle breakdown (GVBD), by inhibiting the burst of protein phosphorylation without changing the rate of incorporation of [35S]methionine into proteins. This effect is reversible; it depends both upon drug concentration and the particular female. When added after GVBD and before the emission of the first polar body, 6-DMAP decreases the level of protein phosphorylation and induces decondensation of the chromosomes and reformation of the nuclear envelope. In contrast, 6-DMAP did not trigger these processes in metaphase II oocytes which only produce resting nuclei when treated by protein synthesis inhibitors. From these data, we conclude that (1) the early appearance and stability of mouse MPF in Metaphase I oocytes depend on protein phosphorylation rather than on protein synthesis, and (2) protein synthesis is necessary to maintain the condensation of the chromosomes in metaphase II oocytes.

Effects of 6-dimethylaminopurine on microtubules and putative intermediate filaments in sea urchin embryos.

The effects of 6-dimethylaminopurine (6-DMAP) (a putative phosphorylation inhibitor) on the state of assembly of microtubules and intermediate filaments have been studied during the first cell cycle of the sea urchin Strongylocentrotus droebachiensis. Changes in the spatial organization of cytoskeletal structures were studied by indirect immunofluorescence with anti-tubulin and anti-IFa antibodies. The rates and patterns of protein phosphorylation in control and treated eggs were also investigated. The transfer of fertilized eggs to 600 microM 6-DMAP within 4 min following insemination inhibits pronuclear migration and syngamy. This also prevents male pronuclear decondensation, while chromatin condensation and nuclear envelope breakdown do not occur in the female pronucleus. Immunolabeling with anti-tubulin antibodies reveals the presence of cortical microtubules as early as 15 min after fertilization in both control and treated eggs. However, no sperm astral microtubules could be detected in the treated eggs. At later stages, from syngamy (40 min) up to nuclear envelope breakdown (90 min), 6-DMAP affects neither cortical microtubule organization nor the state of chromatin condensation but it precludes nuclear envelope breakdown and entry into mitosis. Treatment of the fertilized eggs after nuclear envelope breakdown induces permanent chromosome decondensation and premature disappearance of the mitotic apparatus. This last event involves disruption of the spatial organization of both microtubules and putative intermediate filaments. Quantitative measurements of protein phosphorylation show that 6-DMAP efficiently and reversibly inhibits 32P incorporation into proteins. Qualitative analysis of the autoradiograms of 32P-labeled proteins separated by SDS-PAGE reveals that a major protein band, migrating with an apparent molecular weight of 31 x 10(3)Mr, is specifically dephosphorylated in eggs treated with 6-DMAP. This study suggests that protein phosphorylation is required for sperm aster microtubule growth and migration, but not for cortical microtubule polymerization. It also strengthens the hypothesis that, in sea urchin eggs, putative intermediate filaments are tightly associated with spindle microtubules. Finally, it confirms that inhibiting protein phosphorylation before nuclear envelope breakdown reversibly prevents the entry into mitosis.

[Neural determination in Xenopus laevis embryos: control of early neural gene expression by calcium]. / La détermination neurale dans l'embryon de Xenopus laevis: contrôle de l'expression des gènes neuraux précoces par le calcium.

In amphibian embryos the central nervous system derives from the dorsal region of the ectoderm. Molecular studies led to the formulation of the "neural default model" in which neural development is under the inhibitory control of members of the BMP family. These growth factors also act as epidermis inducers. The neural fate is revealed by factors secreted by the Spemann Organizer such as noggin, chordin, follistatin, Xnr3 and cerberus which act by blocking BMP signalling. We propose a new model for neural cell determination in which a signalling pathway controlled by an increase in intracellular calcium suppresses the epidermis fate and activates the neural fate instead. This increase in calcium is due to an influx through calcium channels of the L-type, expressed in ectodermal cells during gastrulation. The possible involvement of a calcium-dependent phosphatase (calcineurin) to inhibit the epidermis fate and a calcium-calmodulin kinase (CaMkinase II) which activates the neural fate is discussed.

The role of cyclins in the maturation of Patella vulgata oocytes.

We have cloned and sequenced the cDNAs encoding Patella vulgata cyclins A and B. The cDNA clones contain an open reading frame of 426 and 408 amino acids respectively, which present similarity with cyclins from other species. Cyclin A and B RNAs are present as polyadenylated and non-polyadenylated RNA in prophase oocytes and are completely polyadenylated in metaphase I. During the first cleavages after fertilization the level of cyclin A and B mRNAs is high and drops when the free swimming stage is reached. Using p13suc1-Sepharose bead precipitation we demonstrate that cyclin synthesis is triggered during maturation and that inhibition of protein synthesis makes the cyclins disappear rapidly from the metaphase I oocytes, which shift to interphase condition. By microinjecting antisense oligonucleotides into metaphase I oocytes, we demonstrate that in vivo ablation of cyclin A and B messengers together gives the same result, whereas microinjection of only one oligonucleotide does not show any effect.