Cyclin synthesis, modification and destruction during meiotic maturation of the starfish oocyte

A review of mitosis in the fission yeast Schizosaccharomyces pombe

Mitosis and cell division are the final events of the cell cycle, resulting in the precise segregation of chromosomes into two daughter cells. A highly controlled and accurate segregation of the chromosomes is required to ensure that each daughter cell receives a complete genome and remains viable. The fission yeast, Schizosaccharomyces pombe, is a unicellular eukaryotic organism which is particularly convenient for investigating these problems. It is very amenable to genetic analysis and its predominantly haploid life cycle has allowed the isolation of recessive temperature-sensitive mutants unable to complete the cell cycle. Classical genetic analysis of these mutants has been used to identify over 40 gene functions that are required for cell cycle progress in S. pombe. Many of these genes have now been cloned and sequenced and in some cases the encoded gene product has been identified. This approach, coupling classical and molecular genetics, allows identification of the molecules important in the mitotic processes and provides a means for establishing what functional roles they may play.

Isolation of a human cyclin cDNA: evidence for cyclin mRNA and protein regulation in the cell cycle and for interaction with p34cdc2

This paper reports the nucleotide and predicted amino acid sequence of a human B-type cyclin. The predicted protein sequence shows strong homology to the other known cyclins in the central third of the protein. We show that the level of cyclin mRNA is regulated during the cell cycle, increasing during G2 phase to four time that present in G1. The protein accumulates steadily during G2 to at least 20 times its level in G1 and is abruptly destroyed at mitosis. In G2/M phase, cyclin is associated with p34cdc2, the human homolog of the fission yeast gene cdc2+, and this complex has histone H1 kinase activity.

Mammalian growth-associated H1 histone kinase: a homolog of cdc2+/CDC28 protein kinases controlling mitotic entry in yeast and frog cells

Mammalian growth-associated H1 histone kinase, an enzyme whose activity is sharply elevated at mitosis, is similar to cdc2+ protein kinase from Schizosaccharomyces pombe and CDC28 protein kinase from Saccharomyces cerevisiae with respect to immunoreactivity, molecular size, and specificity for phosphorylation sites in H1 histone. Phosphorylation of specific growth-associated sites in H1 histone is catalyzed by yeast cdc2+/CDC28 kinase, as shown by the in vitro thermal lability of this activity in extracts prepared from temperature-sensitive mutants. In addition, highly purified Xenopus maturation-promoting factor catalyzes phosphorylation of the same sites in H1 as do the mammalian and yeast kinases. The data indicate that growth-associated H1 kinase is encoded by a mammalian homolog of cdc2+/CDC28 protein kinase, which controls entry into mitosis in yeast and frog cells. Since H1 histone is known to be an in vivo substrate of the mammalian kinase, this suggests that phosphorylation of H1 histone or an H1 histone counterpart is an important component of the mechanism for entry of cells into mitosis.

Microinjection of antisense c-mos oligonucleotides prevents meiosis II in the maturing mouse egg

Injection of antisense oligonucleotides was used to investigate the function of c-mos in murine oocytes. Oocytes injected with antisense c-mos oligonucleotides completed the first meiotic division but failed to initiate meiosis II. Instead, loss of c-mos function led to chromosome decondensation, reformation of a nucleus after meiosis I, and cleavage to two cells. Therefore, c-mos is required for meiosis II during murine oocyte maturation.

Cyclin is a component of the sea urchin egg M-phase specific histone H1 kinase

A so-called 'growth-associated' or 'M-phase specific' histone H1 kinase (H1K) has been described in a wide variety of eukaryotic cell types; p34cdc2 has previously been shown to be a catalytic subunit of this protein kinase. In fertilized sea urchin eggs the activity of H1K oscillates during the cell division cycle and there is a striking temporal correlation between H1K activation and the accumulation of a phosphorylated form of cyclin. H1K activity declines in parallel with proteolytic cyclin destruction of the end of the first cell cycle. By virtue of the high affinity of the fission yeast p13suc1 for the p34cdc2 protein, H1K strongly binds to p13-Sepharose beads. Cyclin, p34cdc2 and H1K co-purify on this affinity reagent as well as through several conventional chromatographic procedures. Anticyclin antibodies immunoprecipitate the M-phase specific H1K in crude extracts or in purified fractions. Sea urchin eggs appear to contain much less cyclin than p34cdc2, suggesting that p34cdc2 may interact with other proteins. These results demonstrate that cyclin and p34cdc2 are major components of the M-phase specific H1K.

Regulation of p34cdc2 protein kinase during mitosis

The cell-cycle timing of mitosis in fission yeast is determined by the cdc25+ gene product activating the p34cdc2 protein kinase leading to mitotic initiation. Protein kinase activity remains high in metaphase and then declines during anaphase. Activation of the protein kinase also requires the cyclin homolog p56cdc13, which also functions post activation at a later stage of mitosis. The continuing function of p56cdc13 during mitosis is consistent with its high level until the metaphase/anaphase transition. At anaphase the p56cdc13 level falls dramatically just before the decline in p34cdc2 protein kinase activity. The behavior of p56cdc13 is similar to that observed for cyclins in oocytes. p13suc1 interacts closely with p34cdc2; it is required during the process of mitosis and may play a role in the inactivation of the p34cdc2 protein kinase. Therefore, the cdc25+, cdc13+, and suc1+ gene products are important for regulating p34cdc2 protein kinase activity during entry into, progress through, and exit from mitosis.

Cyclin synthesis drives the early embryonic cell cycle

We have produced extracts of frog eggs that can perform multiple cell cycles in vitro. Destruction of the endogenous messenger RNA arrests the extracts in interphase. The addition of exogenous cyclin mRNA is sufficient to produce multiple cell cycles. The newly synthesized cyclin protein accumulates during each interphase and is degraded at the end of each mitosis.

Purification of MPF from starfish: identification as the H1 histone kinase p34cdc2 and a possible mechanism for its periodic activation

MPF extracted from starfish oocytes copurifies with an M phase-specific H1 histone kinase encoded by a homolog of the fission yeast cell cycle control gene cdc2+. The most purified preparations contain p34cdc2 as the only major protein. Activation of the p34cdc2 kinase is correlated with appearance of the MPF activity both in vivo and in vitro. The increase in protein kinase activity is associated with p34cdc2 dephosphorylation and the decrease in protein kinase activity on leaving M phase with rephosphorylation. Microinjection of a peptide perfectly conserved in p34cdc2 from yeast to humans induces meiotic maturation, suggesting that an inhibitory component in G2 arrested oocytes interacts with this region of the p34cdc2 kinase. We propose that initiation of M phase is brought about by the dephosphorylation of p34cdc2, leading to increase in its protein kinase activity.

The role of cyclin B in meiosis I

In clams, fertilization is followed by the prominent synthesis of two cyclins, A and B. During the mitotic cell cycles, the two cyclins are accumulated and then destroyed near the end of each metaphase. Newly synthesized cyclin B is complexed with a small set of other proteins, including a kinase that phosphorylates cyclin B in vitro. While both cyclins can act as general inducers of entry into M phase, the two are clearly distinguished by their amino acid sequences (70% nonidentity) and by their different modes of expression in oocytes and during meiosis. In contrast to cyclin A, which is stored solely as maternal mRNA, oocytes contain a stockpile of cyclin B protein, which is stored in large, rapidly sedimenting aggregates. Fertilization results in the release of cyclin B to a more disperse, soluble form. Since the first meiotic division in clams can proceed even when new protein synthesis is blocked, these results strongly suggest it is the fertilization-triggered unmasking of cyclin B protein that drives cells into meiosis I. We propose that the unmasking of maternal cyclin B protein allows it to interact with cdc2 protein kinase, which is also stored in oocytes, and that the formation of this cyclin B/cdc2 complex generates active M phase-promoting factor.

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.

Translation of cyclin mRNA is necessary for extracts of activated xenopus eggs to enter mitosis

The cyclins are a family of proteins encoded by maternal mRNA. Cyclin polypeptides accumulate during interphase and are destroyed during mitosis at about the time of entry into anaphase. We show here that Xenopus oocytes contain mRNAs encoding two cyclins that are major translation products in a cell-free extract from activated eggs. Cutting these mRNAs with antisense oligonucleotides and endogenous RNAase H blocks entry into mitosis in a cell-free egg extract. The extracts can enter mitosis if either of the cyclin mRNAs is left intact. We conclude that the synthesis of these cyclins is necessary for mitotic cell cycles in cleaving Xenopus embryos.

Expression and function of Drosophila cyclin A during embryonic cell cycle progression

Cyclin proteins are thought to trigger entry into mitosis. During mitosis they are rapidly degraded. Therefore, mitosis and consequently cyclin degradation might be triggered at a time when cyclins have reaccumulated to a critical level. We cloned and sequenced a Drosophila cyclin A homolog and identified mutations in the corresponding gene. Immunofluorescent staining revealed that cyclin A accumulates in the interphase cytoplasm of cellularized embryos, but relocates to the nuclear region early in prophase and is completely degraded within metaphase. Cyclin A was expressed in dividing cells throughout development, and a functional cyclin A gene was required for continued division after exhaustion of maternally contributed cyclin A. Importantly, the timing of post cellularization divisions was not governed by the rate of accumulation or level of cyclin A.

Transcripts of one of two Drosophila cyclin genes become localized in pole cells during embryogenesis

Cyclins, originally discovered in the eggs of marine invertebrates, are proteins which undergo dramatic cycles of synthesis followed by degradation at the metaphase-anaphase transition of cell division. That they participate in the G2-M transition is supported by the fact that when synthetic cyclin messenger RNAs from clam and sea urchin are microinjected into the G2-arrested oocytes of Xenopus, they induce maturation. The cyclin of fission yeast is the product of the cdc13 gene, which is known to interact with cdc2, a gene required for the entry into mitosis. We have cloned the genes that encode A-type and B-type cyclins from Drosophila melanogaster by virtue of their sequence similarity to oligonucleotides corresponding to conserved regions of the cyclin genes. We show that both genes encode abundant maternal mRNAs, but whereas the cyclin A mRNA is relatively uniformly distributed before cell formation, the cyclin B mRNA becomes localized to the developing pole cells. In larvae, cyclin A is expressed predominantly in brain and imaginal disks, whereas cyclin B transcripts are abundant in testes.

Cdc2 protein kinase is complexed with both cyclin A and B: evidence for proteolytic inactivation of MPF

In the clam, Spisula, two previously described proteins known as cyclin A and B display the unusual property of selective proteolytic degradation at the end of each mitosis. We show here that clam oocytes and embryos contain a cdc2 protein kinase. This protein kinase is a component of the M phase promoting factor (MPF) in frog eggs and the M phase-specific histone H1 kinase in starfish. Clam cdc2 is found in association with both cyclin A and B, probably not as a trimolecular association, but as separate cdc2/cyclin A and cdc2/cyclin B complexes. Clam cdc2 and the associated cyclins bind to p13suc1-Sepharose. The p13-bound complex, and also anti-cyclin A or B immunoprecipitates, each display cell cycle-dependent histone H1 kinase activity. We suggest that in addition to the cdc2 protein kinase, the cyclins are further components of the M phase promoting factor and that cyclin proteolysis provides the mechanism of MPF inactivation and thus exit from mitosis.

Nuclear and cytoplasmic mitotic cycles continue in Drosophila embryos in which DNA synthesis is inhibited with aphidicolin

We have microinjected aphidicolin, a specific inhibitor of DNA polymerase alpha, into syncytial Drosophila embryos. This treatment inhibits DNA synthesis and, as a consequence, nuclear replication. We demonstrate that under these conditions several cycles of both centrosome replication and cortical budding continue, although the cycles have a longer periodicity than is normally found. As in uninjected embryos, when the cortical buds are present, the embryos have nuclei containing decondensed chromatin surrounded by nuclear membranes as judged by bright annular staining with an anti-lamin antibody. As the buds recede, the unreplicated chromatin condenses and lamin staining becomes weak and diffuse. Thus, both cytoplasmic and nuclear aspects of the mitotic cycle continue following the inhibition of DNA replication in the Drosophila embryo.

An M-phase-specific protein kinase of Xenopus oocytes: partial purification and possible mechanism of its periodic activation

The activity of a Ca2+- and cyclic nucleotide-independent protein kinase(s) which catalyzes hyperphosphorylation of a set of endogenous proteins, including a 95-kDa soluble phosphoprotein, is found to fluctuate in both the meiotic and mitotic cell cycles of Xenopus oocytes and activated eggs. The activity is high in M-phase and hardly detectable in interphase. The activity copurifies with a major histone kinase(s) throughout four purification steps: ammonium sulfate precipitation, DEAE-cellulose chromatography, high-performance liquid chromatography on TSK G3000, and CM-Sepharose chromatography. This suggests that a single enzyme shares activity against endogenous proteins and added histones. Changes in the activity of the M-phase-specific protein kinase(s) as assayed in vitro correlate with changes in the extent of protein phosphorylation in oocytes pulse-labeled with 32P-phosphate by microinjection during meiotic maturation and the early embryonic cell cycle. This suggests that the kinase(s) has a broad specificity and plays a key role in the increased protein phosphorylation which occurs at the transition to M-phase. Microinjection of the maturation-promoting factor (MPF) into immature oocytes triggers, after a 10-min lag period, the activation of the M-phase specific kinase(s), even in the absence of protein synthesis. In contrast MPF microinjection does not induce kinase activation in cycloheximide-treated oocytes arrested after completion of the first meiotic cell cycle or in activated eggs arrested in S-phase by incubation in cycloheximide. This suggests that immature oocytes contain an inactive kinase precursor (prokinase) which is synthesized at each of the following cell cycles. In the absence of MPF addition, the prokinase to kinase transition occurs "spontaneously" after a 2-hr lag period in high-speed supernatants prepared from prophase-arrested oocytes if low-molecular-weight metabolites are eliminated by gel filtration. Addition of ATP, but not of AMP-PNP (adenylyl-imidodiphosphate), prevents spontaneous kinase activation in gel-filtered extracts. We propose that MPF activates the M-phase-specific protein kinase in the intact cell by inactivating a factor which requires phosphorylation conditions to inhibit the prokinase to kinase transition.