The inhibition of polo kinase by matrimony maintains G2 arrest in the meiotic cell cycle

Many meiotic systems in female animals include a lengthy arrest in G2 that separates the end of pachytene from nuclear envelope breakdown (NEB). However, the mechanisms by which a meiotic cell can arrest for long periods of time (decades in human females) have remained a mystery. The Drosophila Matrimony (Mtrm) protein is expressed from the end of pachytene until the completion of meiosis I. Loss-of-function mtrm mutants result in precocious NEB. Coimmunoprecipitation experiments reveal that Mtrm physically interacts with Polo kinase (Polo) in vivo, and multidimensional protein identification technology mass spectrometry analysis reveals that Mtrm binds to Polo with an approximate stoichiometry of 1:1. Mutation of a Polo-Box Domain (PBD) binding site in Mtrm ablates the function of Mtrm and the physical interaction of Mtrm with Polo. The meiotic defects observed in mtrm/+ heterozygotes are fully suppressed by reducing the dose of polo⁺, demonstrating that Mtrm acts as an inhibitor of Polo. Mtrm acts as a negative regulator of Polo during the later stages of G2 arrest. Indeed, both the repression of Polo expression until stage 11 and the inactivation of newly synthesized Polo by Mtrm until stage 13 play critical roles in maintaining and properly terminating G2 arrest. Our data suggest a model in which the eventual activation of Cdc25 by an excess of Polo at stage 13 triggers NEB and entry into prometaphase.     

The Cdc20 (Fzy)/Cdh1-related protein, Cort, cooperates with Fzy in cyclin destruction and anaphase progression in meiosis I and II in Drosophila

Meiosis is a highly specialized cell division that requires significant reorganization of the canonical cell-cycle machinery and the use of meiosis-specific cell-cycle regulators. The anaphase-promoting complex (APC) and a conserved APC adaptor, Cdc20 (also known as Fzy), are required for anaphase progression in mitotic cells. The APC has also been implicated in meiosis, although it is not yet understood how it mediates these non-canonical divisions. Cortex (Cort) is a diverged Fzy homologue that is expressed in the female germline of Drosophila, where it functions with the Cdk1-interacting protein Cks30A to drive anaphase in meiosis II. Here, we show that Cort functions together with the canonical mitotic APC adaptor Fzy to target the three mitotic cyclins (A, B and B3) for destruction in the egg and drive anaphase progression in both meiotic divisions. In addition to controlling cyclin destruction globally in the egg, Cort and Fzy appear to both be required for the local destruction of cyclin B on spindles. We find that cyclin B associates with spindle microtubules throughout meiosis I and meiosis II, and dissociates from the meiotic spindle in anaphase II. Fzy and Cort are required for this loss of cyclin B from the meiotic spindle. Our results lead to a model in which the germline-specific APC(Cort) cooperates with the more general APC(Fzy), both locally on the meiotic spindle and globally in the egg cytoplasm, to target cyclins for destruction and drive progression through the two meiotic divisions.     

Developmental role and regulation of cortex, a meiosis-specific anaphase-promoting complex/cyclosome activator

During oogenesis in metazoans, the meiotic divisions must be coordinated with development of the oocyte to ensure successful fertilization and subsequent embryogenesis. The ways in which the mitotic machinery is specialized for meiosis are not fully understood. cortex, which encodes a putative female meiosis-specific anaphase-promoting complex/cyclosome (APC/C) activator, is required for proper meiosis in Drosophila. We demonstrate that CORT physically associates with core subunits of the APC/C in ovaries. APC/C^CORT targets Cyclin A for degradation prior to the metaphase I arrest, while Cyclins B and B3 are not targeted until after egg activation. We investigate the regulation of CORT and find that CORT protein is specifically expressed during the meiotic divisions in the oocyte. Polyadenylation of cort mRNA is correlated with appearance of CORT protein at oocyte maturation, while deadenylation of cort mRNA occurs in the early embryo. CORT protein is targeted for degradation by the APC/C following egg activation, and this degradation is dependent on an intact D-box in the C terminus of CORT. Our studies reveal the mechanism for developmental regulation of an APC/C activator and suggest it is one strategy for control of the female meiotic cell cycle in a multicellular organism.     

An Amino-Terminal Polo Kinase Interaction Motif Acts in the Regulation of Centrosome Formation and Reveals a Novel Function for centrosomin (cnn) in Drosophila

The formation of the pericentriolar matrix (PCM) and a fully functional centrosome in syncytial Drosophila melanogaster embryos requires the rapid transport of Cnn during initiation of the centrosome replication cycle. We show a Cnn and Polo kinase interaction is apparently required during embryogenesis and involves the exon 1A-initiating coding exon, suggesting a subset of Cnn splice variants is regulated by Polo kinase. During PCM formation exon 1A Cnn-Long Form proteins likely bind Polo kinase before phosphorylation by Polo for Cnn transport to the centrosome. Loss of either of these interactions in a portion of the total Cnn protein pool is sufficient to remove native Cnn from the pool, thereby altering the normal localization dynamics of Cnn to the PCM. Additionally, Cnn-Short Form proteins are required for polar body formation, a process known to require Polo kinase after the completion of meiosis. Exon 1A Cnn-LF and Cnn-SF proteins, in conjunction with Polo kinase, are required at the completion of meiosis and for the formation of functional centrosomes during early embryogenesis.     

A Wee1 checkpoint inhibits anaphase onset

Cdk1 drives both mitotic entry and the metaphase-to-anaphase transition. Past work has shown that Wee1 inhibition of Cdk1 blocks mitotic entry. Here we show that the budding yeast Wee1 kinase, Swe1, also restrains the metaphase-to-anaphase transition by preventing Cdk1 phosphorylation and activation of the mitotic form of the anaphase-promoting complex/cyclosome (APC^Cdc20). Deletion of SWE1 or its opposing phosphatase MIH1 (the budding yeast cdc25⁺) altered the timing of anaphase onset, and activation of the Swe1-dependent morphogenesis checkpoint or overexpression of Swe1 blocked cells in metaphase with reduced APC activity in vivo and in vitro. The morphogenesis checkpoint also depended on Cdc55, a regulatory subunit of protein phosphatase 2A (PP2A). cdc55Δ checkpoint defects were rescued by mutating 12 Cdk1 phosphorylation sites on the APC, demonstrating that the APC is a target of this checkpoint. These data suggest a model in which stepwise activation of Cdk1 and inhibition of PP2A^Cdc55 triggers anaphase onset.     

Cell Cycle Regulation of the Saccharomyces cerevisiae Polo-Like Kinase Cdc5p

Progression through and completion of mitosis require the actions of the evolutionarily conserved Polo kinase. We have determined that the levels of Cdc5p, a Saccharomyces cerevisiae member of the Polo family of mitotic kinases, are cell cycle regulated. Cdc5p accumulates in the nuclei of G₂/M-phase cells, and its levels decline dramatically as cells progress through anaphase and begin telophase. We report that Cdc5p levels are sensitive to mutations in key components of the anaphase-promoting complex (APC). We have determined that Cdc5p-associated kinase activity is restricted to G₂/M and that this activity is posttranslationally regulated. These results further link the actions of the APC to the completion of mitosis and suggest possible roles for Cdc5p during progression through and completion of mitosis.     

High endogenous activated protein C levels attenuates bleomycin‐induced pulmonary fibrosis

Coagulation activation accompanied by reduced anticoagulant activity is a key characteristic of patients with idiopathic pulmonary fibrosis (IPF). Although the importance of coagulation activation in IPF is well studied, the potential relevance of endogenous anticoagulant activity in IPF progression remains elusive. We assess the importance of the endogenous anticoagulant protein C pathway on disease progression during bleomycin‐induced pulmonary fibrosis. Wild‐type mice and mice with high endogenous activated protein C APC levels (APC^high) were subjected to bleomycin‐induced pulmonary fibrosis. Fibrosis was assesses by hydroxyproline and histochemical analysis. Macrophage recruitment was assessed immunohistochemically. In vitro, macrophage migration was analysed by transwell migration assays. Fourteen days after bleomycin instillation, APC^high mice developed pulmonary fibrosis to a similar degree as wild‐type mice. Interestingly, Aschcroft scores as well as lung hydroxyproline levels were significantly lower in APC^high mice than in wild‐type mice on day 28. The reduction in fibrosis in APC^high mice was accompanied by reduced macrophage numbers in their lungs and subsequent in vitro experiments showed that APC inhibits thrombin‐dependent macrophage migration. Our data suggest that high endogenous APC levels inhibit the progression of bleomycin‐induced pulmonary fibrosis and that APC modifies pulmonary fibrosis by limiting thrombin‐dependent macrophage recruitment.     

Genetic and Proteomic Evidence for Roles of Drosophila SUMO in Cell Cycle Control,Ras Signaling,and Early Pattern Formation

SUMO is a protein modifier that is vital for multicellular development. Here we present the first system-wide analysis, combining multiple approaches, to correlate the sumoylated proteome (SUMO-ome) in a multicellular organism with the developmental roles of SUMO. Using mass-spectrometry-based protein identification, we found over 140 largely novel SUMO conjugates in the early Drosophila embryo. Enriched functional groups include proteins involved in Ras signaling, cell cycle, and pattern formation. In support of the functional significance of these findings, sumo germline clone embryos exhibited phenotypes indicative of defects in these same three processes. Our cell culture and immunolocalization studies further substantiate roles for SUMO in Ras signaling and cell cycle regulation. For example, we found that SUMO is required for efficient Ras-mediated MAP kinase activation upstream or at the level of Ras activation. We further found that SUMO is dynamically localized during mitosis to the condensed chromosomes, and later also to the midbody. Polo kinase, a SUMO substrate found in our screen, partially colocalizes with SUMO at both sites. These studies show that SUMO coordinates multiple regulatory processes during oogenesis and early embryogenesis. In addition, our database of sumoylated proteins provides a valuable resource for those studying the roles of SUMO in development.     

Regulation of the Anaphase-promoting Complex/Cyclosome by bimAAPC3 and Proteolysis of NIMA

Surprisingly, although highly temperature-sensitive, the bimA1^APC3 anaphase-promoting complex/cyclosome (APC/C) mutation does not cause arrest of mitotic exit. Instead, rapid inactivation of bimA1^APC3 is shown to promote repeating oscillations of chromosome condensation and decondensation, activation and inactivation of NIMA and p34^cdc2 kinases, and accumulation and degradation of NIMA, which all coordinately cycle multiple times without causing nuclear division. These bimA1^APC3-induced cell cycle oscillations require active NIMA, because a nimA5 + bimA1^APC3 double mutant arrests in a mitotic state with very high p34^cdc2 H1 kinase activity. NIMA protein instability during S phase and G2 was also found to be controlled by the APC/C. The bimA1^APC3 mutation therefore first inactivates the APC/C but then allows its activation in a cyclic manner; these cycles depend on NIMA. We hypothesize that bimA^APC3 could be part of a cell cycle clock mechanism that is reset after inactivation of bimA1^APC3. The bimA1^APC3 mutation may also make the APC/C resistant to activation by mitotic substrates of the APC/C, such as cyclin B, Polo, and NIMA, causing mitotic delay. Once these regulators accumulate, they activate the APC/C, and cells exit from mitosis, which then allows this cycle to repeat. The data indicate that bimA^APC3 regulates the APC/C in a NIMA-dependent manner.     

Matrimony ties Polo down: Can this kinase get free?

Cell cycle progression in female meiotic systems is characterized by the presence of two or more pre-programmed arrests. One such arrest is invariable throughout all species—a lengthy G₂ arrest that separates the end of pachytene (by which time homologous chromosomes have condensed, paired, and undergone recombination1) from nuclear envelope breakdown (NEB). The termination of G₂ arrest (as defined by NEB) and the subsequent entry of the oocyte into prometaphase is regulated by an intracellular signaling cascade whose ultimate feature is the activation of the cyclin B-Cdk1 complex by the Cdc25 phosphatase family. In oocytes, activation of Cdc25 is often mediated by Polo-like kinases (Plks).(2-6) Recent work by Xiang et al. demonstrated that in Drosophila female meiosis, Polo’s role in promoting NEB is regulated by a meiosis-specific stoichiometric inhibitor called Matrimony (Mtrm), which binds to the C-terminal Polo-box domain (PBD) of Polo.(7) In addition to a PBD-binding site, Mtrm contains putative Plk and cyclin B-Cdk1 phosphorylation consensus motifs. These motifs suggest a unique mechanism of Polo inhibition by Mtrm and a possible auto-amplification loop by which cyclin B-Cdk1-mediated destruction or dissociation of Mtrm from Polo allows for rapid and irreversible G₂ exit and entry into prometaphase.     

The C. elegans DYRK Kinase MBK-2 Marks Oocyte Proteins for Degradation in Response to Meiotic Maturation

The oocyte-to-embryo transition transforms a differentiated germ cell into a totipotent zygote capable of somatic development. In C. elegans, several oocyte proteins, including the meiotic katanin subunit MEI-1 and the oocyte maturation protein OMA-1, must be degraded during this transition . Degradation of MEI-1 and OMA-1 requires the dual-specificity YAK-1-related (DYRK) kinase MBK-2 . Here, we demonstrate that MBK-2 directly phosphorylates MEI-1 and OMA-1 in vitro and that this activity is essential for degradation in vivo. Phosphorylation of MEI-1 by MBK-2 reaches maximal levels after the meiotic divisions, immediately preceding MEI-1 degradation. MEI-1 phosphorylation and degradation still occur in spe-9 eggs, which undergo meiotic maturation and exit in the absence of fertilization . In contrast, MEI-1 phosphorylation and degradation are blocked in cell-cycle mutants that arrest during the meiotic divisions, and are accelerated in wee-1.3(RNAi) oocytes, which prematurely enter meiotic M phase (A. Golden, personal communication). A GFP:MBK-2 fusion relocalizes from the cortex to the cytoplasm during the meiotic divisions, and this relocalization also depends on cell-cycle progression. Our findings suggest that regulators of meiotic M phase activate a remodeling program, independently of fertilization, to prepare eggs for embryogenesis.     

Rho GTPase Cdc42 is a direct interacting partner of Adenomatous Polyposis Coli protein and can alter its cellular localization

Adenomatous Polyposis Coli (APC) is a tumor suppressor gene product involved in colon cancer. APC is a large multidomain molecule of 2843 amino acid residues and connects cell-cell adhesion, the F-actin/microtubule cytoskeleton and the nucleus. Here we show that Cdc42 interacts directly with the first three armadillo repeats of APC by yeast two-hybrid screens. We confirm the Cdc42-APC interaction using pulldown assays in vitro and FRET assays in vivo. Interestingly, Cdc42 interacts with APC at leading edge sites where F-actin is enriched. In contrast, Cdc42 interacts with the truncated mutant APC^1–1638 in cellular puncta associated with the golgi-lysozome pathway in transfected CHO cells. In HCT116 and SW480 cells, Cdc42 induces the relocalization of endogenous APC and the mutant APC^1–1338 to the plasma membrane and cellular puncta, respectively. Taken together, these data indicate that the Cdc42-APC interaction induces localization of both APC and mutant APC and may thus play a direct role in the functions of these proteins.     

The careful control of Polo kinase by APC/C-Ube2C ensures the intercellular transport of germline centrosomes during Drosophila oogenesis

A feature of metazoan reproduction is the elimination of maternal centrosomes from the oocyte. In animals that form syncytial cysts during oogenesis, including Drosophila and human, all centrosomes within the cyst migrate to the oocyte where they are subsequently degenerated. The importance and the underlying mechanism of this event remain unclear. Here, we show that, during early Drosophila oogenesis, control of the Anaphase Promoting Complex/Cyclosome (APC/C), the ubiquitin ligase complex essential for cell cycle control, ensures proper transport of centrosomes into the oocyte through the regulation of Polo/Plk1 kinase, a critical regulator of the integrity and activity of the centrosome. We show that novel mutations in the APC/C-specific E2, Vihar/Ube2c, that affect its inhibitory regulation on APC/C cause precocious Polo degradation and impedes centrosome transport, through destabilization of centrosomes. The failure of centrosome migration correlates with weakened microtubule polarization in the cyst and allows ectopic microtubule nucleation in nurse cells, leading to the loss of oocyte identity. These results suggest a role for centrosome migration in oocyte fate maintenance through the concentration and confinement of microtubule nucleation activity into the oocyte. Considering the conserved roles of APC/C and Polo throughout the animal kingdom, our findings may be translated into other animals.     

Program of early development in the mammal: changes in patterns and absolute rates of tubulin and total protein synthesis during oogenesis and early embryogenesis in the mouse.

The absolute rates of total protein synthesis and tubulin synthesis during oogenesis and early embryogenesis in the mouse have been determined by measuring specific activities of the endogenous methionine pool and rates of incorporation of [³⁵S]methionine into total protein and tubulin. The absolute rate of protein synthesis decreases from 43 to 33 pg/hr/oocyte during meiotic maturation, while the size of the endogenous methionine pool remains essentially unchanged at 65 fmole/oocyte (R. M. Schultz, M. J. LaMarca, and P. M. Wassarman, 1978, Proc. Nat. Acad. Sci. USA,75, 4160). The one-cell mouse embryo synthesizes protein at a rate of 45 pg/hr/embryo, so that fertilization is accompanied by about a 40% increase in the absolute rate of total protein synthesis. The eight-cell compacted embryo synthesizes protein at the rate of 51 pg/hr/embryo. The size of the endogenous methionine pool increases dramatically during early embryogenesis, from 74 fmole in the unfertilized ovum to 137 and 222 fmole in the one-cell embryo and eight-cell compacted embryo, respectively. Tubulin is one of the major proteins synthesized by the mouse oocyte and embryo since the absolute rate of tubulin synthesis is, on the average, 1.3% that of total protein synthesis. The absolute rate of tubulin synthesis decreases from 0.61 to 0.36 pg/hr/oocyte during meiotic maturation and then increases to 0.60 pg/hr/embryo in the one-cell embryo and to 0.66 pg/hr/embryo in the eight-cell compacted embryo. During meiotic maturation and early embryogenesis the direction and magnitude of changes in the rate of tubulin synthesis closely parallel those of total protein synthesis. Although equimolar amounts of tubulin subunits are present in microtubules, the ratio of the absolute rate of synthesis of the β subunit to that of the α subunit is about 2.0 throughout meiotic maturation and early embryogenesis.High-resolution two-dimensional gel electrophoretic analysis of [³⁵S]methionine-labeled proteins reveals that many of the newly synthesized proteins that first appear during meiotic maturation of the oocyte continue to be synthesized in the one-cell embryo. Nearly all of the proteins synthesized in the one-cell embryo are also synthesized in the unfertilized ovum, although some changes in the pattern of protein synthesis are associated with fertilization. Therefore, the developmental program for early embryogenesis in the mouse appears to be activated during meiotic maturation of the oocyte. These results are compared with those obtained using oocytes and embryos from nonmammalian animal species.     

Embryogenic and callus-specific proteins in somatic embryogenesis of the grass,Dactylis glomerata L.

Somatic embryogenesis occurs spontaneously in some monocotyledoneous callus and cell suspension cultures maintained in suitable culture conditions. Nevertherless, the processes involved in somatic embryo development, and factors inducing this differentiation, are poorly understood. In order to study the changes in protein composition accompanying embryogenesis in cell suspension cultures of Dactylis glomerata L., embryos of various sizes and “undifferentiated” callus cells were separated and their total cellular protein extracts analyzed by two-dimensional polyacrylamide gel electrophoresis. Several proteins could be identified that are specific for embryos or callus under various culture conditions. Three independent detection methods were employed: silver-staining of proteins, in vivo labeling of proteins with [³⁵S]methionine, and in vitro translation of poly(A)⁺ RNA. All culture conditions tested, including those that induce embryonic proteins in carrot, fail to induce embryonic proteins in D. glomerata callus cells.     

PP2A-twins is antagonized by greatwall and collaborates with polo for cell cycle progression and centrosome attachment to nuclei in drosophila embryos

Cell division and development are regulated by networks of kinases and phosphatases. In early Drosophila embryogenesis, 13 rapid nuclear divisions take place in a syncytium, requiring fine coordination between cell cycle regulators. The Polo kinase is a conserved, crucial regulator of M-phase. We have recently reported an antagonism between Polo and Greatwall (Gwl), another mitotic kinase, in Drosophila embryos. However, the nature of the pathways linking them remained elusive. We have conducted a comprehensive screen for additional genes functioning with polo and gwl. We uncovered a strong interdependence between Polo and Protein Phosphatase 2A (PP2A) with its B-type subunit Twins (Tws). Reducing the maternal contribution of Polo and PP2A-Tws together is embryonic lethal. We found that Polo and PP2A-Tws collaborate to ensure centrosome attachment to nuclei. While a reduction in Polo activity leads to centrosome detachments observable mostly around prophase, a reduction in PP2A-Tws activity leads to centrosome detachments at mitotic exit, and a reduction in both Polo and PP2A-Tws enhances the frequency of detachments at all stages. Moreover, we show that Gwl antagonizes PP2A-Tws function in both meiosis and mitosis. Our study highlights how proper coordination of mitotic entry and exit is required during embryonic cell cycles and defines important roles for Polo and the Gwl-PP2A-Tws pathway in this process.