Evolution of cyclin B3 shows an abrupt three-fold size increase, due to the extension of a single exon in placental mammals, allowing for new protein-protein interactions.

Cyclin B3 evolution has the unique peculiarity of an abrupt 3-fold increase of the protein size in the mammalian lineage due to the extension of a single exon. We have analyzed the evolution of the gene to define the modalities of this event and the possible consequences on the function of the protein. Database searches can trace the appearance of the gene to the origin of metazoans. Most introns were already present in early metazoans, and the intron-exon structure as well as the protein size were fairly conserved in invertebrates and nonmammalian vertebrates. Although intron gains are considered as rare events, we identified two cases, one at the prochordate-chordate transition and one in murids, resulting from different mechanisms. At the emergence of mammals, the gene was relocated from chromosome 6 of platypus to the X chromosome in marsupials, but the exon extension occurred only in placental mammals. A repetitive structure of 18 amino acids, of uncertain origin, is detectable in the 3,000-nt mammalian exon-encoded sequence, suggesting an extension by multiple internal duplications, some of which are still detectable in the primate lineage. Structure prediction programs suggest that the repetitive structure has no associated three-dimensional structure but rather a tendency for disorder. Splice variant isoforms were detected in several mammalian species but without conserved pattern, notably excluding the constant coexistence of premammalian-like transcripts, without the extension. The yeast two-hybrid method revealed that, in human, the extension allowed new interactions with ten unrelated proteins, most of them with specific three-dimensional structures involved in protein-protein interactions, and some highly expressed in testis, as is cyclin B3. The interactions with activator of cAMP-responsive element modulator in testis (ACT), germ cell-less homolog 1, and chromosome 1 open reading frame 14 remain to be verified in vivo since they may not be expressed at the same stages of spermatogenesis as cyclin B3.

SGEBP, a giant protein from starfish oocytes able to interact with ERK.

The mitogen-activated protein kinase (MAPK) pathway is a key regulator of animal meiotic divisions. It involves cascades of kinases whose specificity has been shown to depend on binding proteins acting as scaffolds. We searched for proteins interacting with starfish extracellular signal-regulated kinase (ERK) using the yeast two-hybrid system. An interacting clone was found to encode the 5' region of a giant 16.7-kb transcript encoded by an intronless gene. The corresponding 630-kDa protein could not be detected by Western blot, but the meiotic spindle was labelled by immunolocalization with an antibody against the ERK-binding domain. A related gene was found in the genome of another starfish species, and similarities were also found to a 42.9-kb open reading frame in the sea urchin genome. Yet, no conserved protein-binding domain was detected in the amino acid sequence(s) compared to all the known motifs. Structure prediction software indicated that the encoded proteins are probably disordered while a query of the disordered protein database indicated some similarity with vertebrates microtubule-associated protein 2 (MAP2). This predicts that SGEBP may function as a space-filling polymer, having a role in both cytoskeleton organization and ERK targeting.

CDK5 is present in sea urchin and starfish eggs and embryos and can interact with p35, cyclin E and cyclin B3.

While most cyclin-dependent kinases (CDKs) are involved in cell cycle control, CDK5 is mostly known for crucial functions in neurogenesis. However, we cloned sea urchin CDK5 from a two-cell stage cDNA library and found that the protein is present in eggs and embryos, up to the pluteus stage, but without associated kinase activity. To investigate the potential for nonneuronal roles, we screened a starfish cDNA library with the yeast two-hybrid system, for possible CDK5 partners. Interactions with clones expressing part of cyclin B3 and cyclin E proteins were found and the full-length cyclins were cloned. These interactions were verified in vitro but not in extracts of starfish oocytes and embryos, at any stages, despite the presence of detectable amounts of CDK5, cyclin B3, and cyclin E. We then looked for p35, the CDK5-specific activator, and cloned the sea urchin ortholog. A sea urchin-specific anomaly in the amino acid sequence is the absence of N-terminal myristoylation signal, but nucleotide environment analysis suggests a much higher probability of translation initiation on the second methionine(Met44), that is associated with a conserved myristoylation signal. p35 was found to associate with CDK5 and, when bacterially produced, to confer protein kinase activity to CDK5 immunoprecipitated from sea urchin eggs and embryos. However, p35 mRNA expression was found to begin only at the end of the blastula stage, and the protein was undetectable at any embryonic stage, suggesting a neuronal role beginning in late larval stages.

Cyclin B synthesis and rapamycin-sensitive regulation of protein synthesis during starfish oocyte meiotic divisions.

Translation of cyclin mRNAs represents an important event for proper meiotic maturation and post-fertilization mitoses in many species. Translational control of cyclin B mRNA has been described to be achieved through two separate but related mechanisms: translational repression and polyadenylation. In this paper, we evaluated the contribution of global translational regulation by the cap-dependent translation repressor 4E-BP (eukaryotic initiation factor 4E-binding protein) on the cyclin B protein synthesis during meiotic maturation of the starfish oocytes. We used the immunosupressant drug rapamycin, a strong inhibitor of cap-dependent translation, to check for the involvement of this protein synthesis during this physiological process. Rapamycin was found to prevent dissociation of 4E-BP from the initiation factor eIF4E and to suppress correlatively a burst of global protein synthesis occurring at the G2/M transition. The drug had no effect on first meiotic division but defects in meiotic spindle formation prevented second polar body emission, demonstrating that a rapamycin-sensitive pathway is involved in this mechanism. While rapamycin affected the global protein synthesis, the drug altered neither the specific translation of cyclin B mRNA nor the expression of the Mos protein. The expression of these two proteins was correlated with the phosphorylation and the dissociation of the cytoplasmic polyadenylation element-binding protein from eIF4E.

Acid Release at Activation and Fertilization of Starfish Oocytes.

Fertilization or activation by ionophore A 23187 induces a transient acid release in prophase-blocked and in maturing oocytes of Asterias rubens and Marthasterias glacialis. 1-Methyladenine-induced maturation is not accompanied by acid release. There is no significant difference in the kinetic and amount of acid release related to the nature of activation or the stage of oocytes in each species. The amount of acid released per oocyte volume is smaller than total "fertilization acid" of sea urchin eggs but comparable to its Na-insensitive component. Cortical reaction can be initiated without significant acid release in ammonia treated oocytes. A burst of sodium influx occurs at activation or fertilization of oocytes. Kinetic and amount of Na influx are comparable to acid release. Vitelline membrane elevation is impaired upon activation of oocytes in the absence of extracellular sodium but a significant although smaller release of acid occurs. This suggests that starfish oocytes release acid by a mechanism differing from the Na+ -H+ exchange of sea urchin eggs.

Affinity Purification of Embryo Proteins Phosphorylated on Tyrosine In Vitro*: (phosphotyrosine/protein phosphorylation/fertilization/affinity chromatography/immobilized antibodies).

Fertilization of the sea urchin egg is accompanied by activation of one or more protein tyrosine kinases which have been shown to phosphorylate a restricted set of egg proteins in vitro. In order to characterize these tyrosine kinase substrates, we have used an antibody specific for phosphotyrosine to prepare an immunoaffinity column capable of binding phosphotyrosine containing proteins. This column bound five 32 P-labelled proteins from detergent extracts of embryo membranes phosphorylated in vitro. All were very tightly membrane associated, requiring detergent solubilization. Phosphoamino acid analysis revealed that each of these proteins was phosphorylated exclusively on tyrosine, indicating that they do not act as substrates for other classes of protein kinases.

Anti-peptide Antibody Identifies a 57 kDa Protein Tyrosine Kinase in the Sea Urchin Egg Cortex: (tyrosine kinase/fertilization/src/egg/antibody).

The egg plasma membrane and cortical structures are highly enriched in protein tyrosine kinase activity which is thought to play an important role in the fertilization process. In order to identify the tyrosine protein kinases in the egg cortex, a site directed polyclonal antibody was produced against a peptide duplicating a conserved region of the catalytic domain of the sea urchin c-abl gene product. The region chosen as an antigen had a high degree of homology (57%) to other protein tyrosine kinases. The antibody was found to bind with a high degree of specificity to a 57 kDa protein tyrosine kinase in S. purpuratus eggs. The antibody was capable of immunoprecipitating the enzyme as a 57 kDa phosphoprotein from purified egg cortex fractions solubilized in NP-40. Immunoprecipitation was completely inhibited by prior incubation of the antibody with the synthetic peptide used as an antigen. Binding of the antibody completely inhibited kinase activity. However, the immunoprecipitated kinase activity could be eluted from the Sepharose-coupled antibody and was shown to have catalytic activity towards a tyrosine containing peptide substrate. The enzyme also underwent autophosphorylation on tyrosine in vitro. Ultrastructural localization of the kinase by immuno-electron microscopy revealed that the enzyme was primarily restricted to the egg plasma membrane.

One Millimeter large Oocytes as a Tool to Study Hormonal Control of Meiotic Maturation in Starfish: Role of the Nucleus in Hormone-stimulated Phosphorylation of Cytoplasmic Proteins: (nucleus/maturation-promoting factor/protein phosphorylation).

Single nuclei (germinal vesicles) manually isolated from large oocytes of the starfish Echinaster sepositus, as well as the complementary anucleated oocytes, were used to investigate the early changes of protein phosphorylation which occur from 1-MeAde addition to germinal vesicle breakdown (GVBD). Stimulation of protein phosphorylation was already evident in the nucleus shortly after 1-MeAde addition (18 min, thus about 0.40x the time required for GVBD), although it began first in the cytoplasm. No translocation of phosphoprotein across the nuclear envelope was detected before GVBD. Presence of the nucleus is not required for the hormone to stimulate protein phosphorylation in the remaining part of the oocytetin:fact the patterns of protein phosphorylation in enucleated oocytes were found to be identical, whether enucleation was performed after or before hormonal treatment. Cytoplasm taken at the time of GVBD from maturing Echinaster oocytes induces meiotic maturation when transferred in stage VI immature oocytes of the amphibian Xenopus laevis.

Changes in the Activity of the Maturation-Promoting Factor Are Correlated with Those of a Major Cyclic AMP and Calcium-Independent Protein Kinase During the First Mitotic Cell Cycles in the Early Starfish Embryo: (cell cycle/maturation-promoting factor/protein kinase/protein synthesis/starfish).

Many studies suggest that MPF activation depends on protein phosphorylation or that MPF is itself a protein kinase. In the present report, cyclic variations of MPF activity have been correlated in vivo with changes in the extent of protein phosphorylation or in vitro with changes of a major protein kinase during the first cell cycles of fertilized starfish eggs. This cycling protein kinase neither requires cAMP nor Ca2+ . Neither colchicine nor aphidicoline, which inhibits cleavage and chromosome replication respectively, was found to suppress the synchronous and cyclic variations of both MPF and protein kinase activities. Protein synthesis was found to be required for both MPF and protein kinase activities to reappear after their simultaneous drop at the time of mitotic or meiotic cleavages. Production of either MPF or protein kinase activities is not the immediate result of protein synthesis since there is a delay at each cell cycle between the time when protein synthesis is required and the time when both MPF and protein kinase activities are produced. This suggests that both MPF and protein kinase activities might involve some post-translational modification of a precursor protein synthesized during the preceeding cell cycle.

Natural synchronisation for the study of cell division in the green unicellular alga Ostreococcus tauri.

Ostreococcus tauri (Prasinophyceae) is a marine unicellular green alga which diverged early in the green lineage. The interest of O. tauri as a potential model to study plant cell division is based on its key phylogenetic position, its simple binary division, a very simple cellular organisation and now the availability of the full genome sequence. In addition O. tauri has a minimal yet complete set of cell cycle control genes. Here we show that division can be naturally synchronised by light/dark cycles and that organelles divide before the nucleus. This natural synchronisation, although being only partial, enables the study of the expression of CDKs throughout the cell cycle. The expression patterns of OtCDKA and OtCDKB were determined both at the mRNA and protein levels. The single OtCDKA gene is constantly expressed throughout the cell cycle, whereas OtCDKB is highly regulated and expressed only in S/G2/M phases. More surprisingly, OtCDKA is not phosphorylated at the tyrosine residue, in contrast to OtCDKB which is strongly phosphorylated during cell division. OtCDKA kinase activity appears before the S phase, indicating a possible role of this protein in the G1/S transition. OtCDKB kinase activity occurs later than OtCDKA, and its tyrosine phosphorylation is correlated to G2/M, suggesting a possible control of the mitotic activity. To our knowledge this is the first organism in the green lineage which showed CDKB tyrosine phosphorylation during cell cycle progression.

CDC2L5, a Cdk-like kinase with RS domain, interacts with the ASF/SF2-associated protein p32 and affects splicing in vivo.

The human CDC2L5 gene encodes a protein of unknown physiological function. This protein is closely related to the cyclin-dependent kinase (Cdks) family and contains an arginine/serine-rich (RS) domain. The Cdks were first identified as crucial regulators of cell-cycle progression, more recently they were found to be involved in transcription and mRNA processing. RS domains are mainly present in proteins regulating pre-mRNA splicing, suggesting CDC2L5 having a possible role in this process. In this study, we demonstrate that CDC2L5 is located in the nucleoplasm, at a higher concentration in speckles, the storage sites for splicing factors. Furthermore, this localization is dependent on the presence of the N-terminal sequence including the RS domain. Then, we report that CDC2L5 directly interacts with the ASF/SF2-associated protein p32, a protein involved in splicing regulation. Overexpression of CDC2L5 constructs disturbs constitutive splicing and switches alternative splice site selection in vivo. These results argue in favor of a functional role of the CDC2L5 kinase in splicing regulation.

Nuclear envelope breakdown may deliver an inhibitor of protein phosphatase 1 which triggers cyclin B translation in starfish oocytes.

In vertebrates, enhanced translation of mRNAs in oocytes and early embryos entering M-phase is thought to occur through polyadenylation, involving binding, hyperphosphorylation and proteolytic degradation of Aurora-activated CPEB. In starfish, an unknown component of the oocyte nucleus is required for cyclin B synthesis following the release of G2/prophase block by hormonal stimulation. We have found that CPEB cannot be hyperphosphorylated following hormonal stimulation in starfish oocytes from which the nucleus has been removed. Activation of Aurora kinase, known to interact with protein phosphatase 1 and its specific inhibitor Inh-2, is also prevented. The microinjection of Inh-2 restores Aurora activation, CPEB hyperphosphorylation and cyclin B translation in enucleated oocytes. Nevertheless, we provide evidence that CPEB is in fact hyperphosphorylated by cdc2, without apparent involvement of Aurora or MAP kinase, and that cyclin B synthesis can be stimulated without previous degradation of phosphorylated CPEB. Thus, the regulation of cyclin B synthesis necessary for progression through meiosis can be explained by an equilibrium between CPEB phosphorylation and dephosphorylation, and both aspects of this control may rely on the sole activation of Cdc2 and subsequent nuclear breakdown.

Atypical regulation of a green lineage-specific B-type cyclin-dependent kinase.

Cyclin-dependent kinases (CDKs) are the main regulators of cell cycle progression in eukaryotes. The role and regulation of canonical CDKs, such as the yeast (Saccharomyces cerevisiae) Cdc2 or plant CDKA, have been extensively characterized. However, the function of the plant-specific CDKB is not as well understood. Besides being involved in cell cycle control, Arabidopsis (Arabidopsis thaliana) CDKB would integrate developmental processes to cell cycle progression. We investigated the role of CDKB in Ostreococcus (Ostreococcus tauri), a unicellular green algae with a minimal set of cell cycle genes. In this primitive alga, at the basis of the green lineage, CDKB has integrated two levels of regulations: It is regulated by Tyr phosphorylation like cdc2/CDKA and at the level of synthesis-like B-type CDKs. Furthermore, Ostreococcus CDKB/cyclin B accounts for the main peak of mitotic activity, and CDKB is able to rescue a yeast cdc28(ts) mutant. By contrast, Ostreococcus CDKA is not regulated by Tyr phosphorylation, and it exhibits a low and steady-state activity from DNA replication to exit of mitosis. This suggests that from a major role in the control of mitosis in green algae, CDKB has evolved in higher plants to assume other functions outside the cell cycle.

MAP kinases regulate unfertilized egg apoptosis and fertilization suppresses death via Ca2+ signaling.

The default fate for eggs from many species is death by apoptosis and thus, successful fertilization depends upon suppression of the maternal death program. Little is known about the molecular triggers which activate this process or how the fertilization signal suppresses the default maternal apoptotic pathway. The MAP kinase (MAPK) family member, ERK, plays a universal and critical role in several stages of oocyte meiotic maturation, and fertilization results in ERK inactivation. In somatic cells, ERK and other MAPK family members, p38 and JNK, provide opposing signals to regulate apoptosis, however, it is not known whether MAPKs play a regulatory role in egg apoptosis, nor whether suppression of apoptosis by fertilization is mediated by MAPK activity. Here we demonstrate that MAPKs are involved in starfish egg apoptosis and we investigate the relationship between the fertilization induced signaling pathway and MAPK activation. ERK is active in post-meiotic eggs just until apoptosis onset and then p38, JNK and a third kinase are activated, and remain active through execution. Sequential activation of ERK and p38 is necessary for apoptosis, and newly synthesized proteins are required both upstream of ERK and downstream of p38 for activation of the full apoptotic program. Fertilization causes a dramatic rise in intracellular Ca2+, and we report that Ca2+ provides a necessary and sufficient pro-survival signal. The Ca2+ pathway following fertilization of both young and aged eggs causes ERK to be rapidly inactivated, but fertilization cannot rescue aged eggs from death, indicating that ERK inactivation is not sufficient to suppress apoptosis.

Molecular cloning, gene localization, and structure of human cyclin B3.

Here we describe the molecular cloning of human cyclin B3, its localization, and its structure. It is localized in the subcentromeric region of the X chromosome, still not completely sequenced by the Human Genome Project. This cyclin B3 is unusually large for a mitotic cyclin. Its mRNAs were found in all tissues and were particularly abundant in testis. At least three splice variants were found in the ORF and three variants in the 5'UTR.

Cybip, a starfish cyclin B-binding protein, is involved in meiotic M-phase exit.

We designed a screen to identify starfish oocyte proteins able to bind monomeric cyclin B by affinity chromatography on a cyclin B splice variant displaying low affinity for cdc2. We identified a 15kDa protein previously described as a cdk-binding protein [Biochim. Biophys. Acta Mol. Cell Res. 1589 (2002) 219-231]. Cybip is encoded by a single polymorphic gene and the native protein is matured by cleaving a signal peptide. We firmly establish the fact that it is a true cyclin B-binding protein, since the recombinant protein binds recombinant cyclin B in absence of any cdk. Finally, we show that the microinjection of GST-cybip, and of anti-cybip antibody, in maturing starfish oocytes, inhibits H1 kinase and MPF inactivation, and first polar body emission.