Cell cycle tyrosine phosphorylation of p34cdc2 and a microtubule-associated protein kinase homolog in Xenopus oocytes and eggs.

We have examined the time course of protein tyrosine phosphorylation in the meiotic cell cycles of Xenopus laevis oocytes and the mitotic cell cycles of Xenopus eggs. We have identified two proteins that undergo marked changes in tyrosine phosphorylation during these processes: a 42-kDa protein related to mitogen-activated protein kinase or microtubule-associated protein-2 kinase (MAP kinase) and a 34-kDa protein identical or related to p34cdc2. p42 undergoes an abrupt increase in its tyrosine phosphorylation at the onset of meiosis 1 and remains tyrosine phosphorylated until 30 min after fertilization, at which point it is dephosphorylated. p42 also becomes tyrosine phosphorylated after microinjection of oocytes with partially purified M-phase-promoting factor, even in the presence of cycloheximide. These findings suggest that MAP kinase, previously implicated in the early responses of somatic cells to mitogens, is also activated at the onset of meiotic M phase and that MAP kinase can become tyrosine phosphorylated downstream from M-phase-promoting factor activation. We have also found that p34 goes through a cycle of tyrosine phosphorylation and dephosphorylation prior to meiosis 1 and mitosis 1 but is not detectable as a phosphotyrosyl protein during the 2nd through 12th mitotic cell cycles. It may be that the delay between assembly and activation of the cyclin-p34cdc2 complex that p34cdc2 tyrosine phosphorylation provides is not needed in cell cycles that lack G2 phases. Finally, an unidentified protein or group of proteins migrating at 100 to 116 kDa increase in tyrosine phosphorylation throughout maturation, are dephosphorylated or degraded within 10 min of fertilization, and appear to cycle between low-molecular-weight forms and high-molecular-weight forms during early embryogenesis.     

Newly synthesized protein(s) must associate with p34cdc2 to activate MAP kinase and MPF during progesterone-induced maturation of Xenopus oocytes.

The meiotic maturation of Xenopus oocytes triggered by progesterone requires new protein synthesis to activate both maturation-promoting factor (MPF) and mitogen-activated protein kinase (MAP kinase). Injection of mRNA encoding mutant p34cdc2 (K33R) that can bind cyclins but lacks protein kinase activity strongly inhibited progesterone-induced activation of both MPF and MAP kinase in Xenopus oocytes. Similar results were obtained by injection of GST-p34cdc2 K33R protein or by injection of a monoclonal antibody (A17) against p34cdc2 that blocks its activation by cyclins. Both the dominant-negative p34cdc2 and monoclonal antibody A17 blocked the accumulation of p39mos and activation of MAP kinase in response to progesterone, as well as blocking the appearance of MPF, although they did not inhibit the translation of p39mos mRNA. These results suggest that: (i) activation of free p34cdc2 by newly made proteins, probably cyclin(s), is normally required for the activation of both MPF and MAP kinase by progesterone in Xenopus oocytes; (ii) the activation of translation of cyclin mRNA normally precedes, and does not require either MPF or MAP kinase activity; and (iii) de novo synthesis and accumulation of p39mos is probably both necessary and sufficient for the activation of MAP kinase in response to progesterone.     

Activation of p34cdc2 kinase by cyclin is negatively regulated by cyclic amp-dependent protein kinase in Xenopus oocytes.

Microinjection of a bacterially expressed stable delta 90 sea urchin cyclin B into Xenopus prophase oocytes, in absence or presence of cycloheximide, provokes the activation of histone H1 kinase and the tyrosine dephosphorylation of p34cdc2. Unexpectedly, when prophase oocytes are submitted to a treatment known to elevate the intracellular cAMP level (3-isobutyl-1-methylxanthine and cholera toxin), delta 90 cyclin has no effect and the oocytes remain blocked in prophase. This inhibition is reverted by the microinjection of the inhibitor of cAMP-dependent protein kinase. When delta 90 cyclin is microinjected into oocytes depleted of endogenous cyclins (cycloheximide-treated metaphase I) and in the presence of a high intracellular concentration of cAMP, p34cdc2 kinase is tyrosine rephosphorylated. Altogether, our results indicate that in Xenopus oocyte, cAMP-dependent protein kinase (A-kinase) controls the formation of the cyclin B/p34cdc2 complex which remains inactive and tyrosine phosphorylated.     

Fission yeast p13 blocks mitotic activation and tyrosine dephosphorylation of the Xenopus cdc2 protein kinase

It has been demonstrated that the Xenopus homolog of the fission yeast cdc2 protein is a component of M phase promoting factor (MPF). We show that the Xenopus cdc2 protein is phosphorylated on tyrosine in vivo, and that this tyrosine phosphorylation varies markedly with the stage of the cell cycle. Tyrosine phosphorylation is high during interphase (in Xenopus oocytes and activated eggs) but absent during M phase (in unfertilized eggs). In vitro activation of pre-MPF from Xenopus oocytes results in tyrosine dephosphorylation of the cdc2 protein and switching-on of its kinase activity. The product of the fission yeast suc1 gene (p13), which inhibits the entry into mitosis in Xenopus extracts, completely blocks tyrosine dephosphorylation and kinase activation. However, p13 has no effect on the activated form of the cdc2 kinase. These findings suggest that p13 controls the activation of the cdc2 kinase, and that tyrosine dephosphorylation is an important step in this process.     

cdc25 is a specific tyrosine phosphatase that directly activates p34cdc2

cdc25 controls the activity of the cyclin-p34cdc2 complex by regulating the state of tyrosine phosphorylation of p34cdc2. Drosophila cdc25 protein from two different expression systems activates inactive cyclin-p34cdc2 and induces M phase in Xenopus oocytes and egg extracts. We find that the cdc25 sequence shows weak but significant homology to a phylogenetically diverse group of protein tyrosine phosphatases. cdc25 itself is a very specific protein tyrosine phosphatase. Bacterially expressed cdc25 directly dephosphorylates bacterially expressed p34cdc2 on Tyr-15 in a minimal system devoid of eukaryotic cell components, but does not dephosphorylate other tyrosine-phosphorylated proteins at appreciable rates. In addition, mutations in the putative catalytic site abolish the in vivo activity of cdc25 and its phosphatase activity in vitro. Therefore, cdc25 is a specific protein phosphatase that dephosphorylates tyrosine and possibly threonine residues on p34cdc2 and regulates MPF activation.     

p34cdc2 is physically associated with and phosphorylated by a cdc2-specific tyrosine kinase.

The mammalian homologue of the yeast cdc2 gene encodes a 34-kilodalton serine/threonine kinase that is a subunit of M phase-promoting factor. Recent studies have shown that p34cdc2 is also a major tyrosine-phosphorylated protein in HeLa cells and that its phosphotyrosine content is cell cycle regulated and related to its kinase activity. Here, we show that cdc2 is physically associated with and phosphorylated in vitro by a highly specific tyrosine kinase. Tyrosine phosphorylation of cdc2 in vitro occurs at tyrosine 15, the same site that is phosphorylated in vivo. The association between the two kinases takes place in the cytosolic compartment and involves cyclin B-associated cdc2. Evidence is presented that a substantial fraction of cytosolic cdc2 is hypophosphorylated, whereas nuclear cdc2 is hyperphosphorylated. Finally, we show that the tyrosine kinase associated with cdc2 may be a 67-kilodalton protein and is distinct from src, abl, fms, and other previously reported tyrosine kinases.     

The Xenopus cdc2 protein is a component of MPF, a cytoplasmic regulator of mitosis

In Xenopus, a cytoplasmic agent known as MPF induces entry into mitosis. In fission yeast, genetic studies have shown that the cdc2 kinase regulates mitotic initiation. The 13 kd product of the suc1 gene interacts with the cdc2 kinase in yeast cells. We show that the yeast suc1 gene product (p13) is a potent inhibitor of MPF in cell-free extracts from Xenopus eggs. p13 appears to exert its antagonistic effect by binding directly to MPF. MPF activity is quantitatively depleted by chromatography on a p13 affinity column. Concomitantly, the Xenopus counterpart of the yeast cdc2 protein is adsorbed to the column. A 42 kd protein also binds specifically to the p13 affinity matrix. These findings suggest that the Xenopus cdc2 protein and the 42 kd protein are components of MPF.     

p80cdc25 mitotic inducer is the tyrosine phosphatase that activates p34cdc2 kinase in fission yeast.

We have investigated the mechanism by which fission yeast p80cdc25 induces mitosis. The in vivo active domain was localized to the C-terminal 23 kDa of p80cdc25. This domain produced as a bacterial fusion protein (GST-cdc25) caused tyrosyl dephosphorylation and activation of immunoprecipitated p34cdc2. Furthermore, GST-cdc25 dephosphorylated both para-nitrophenyl-phosphate (pNPP) and casein phosphorylated on serine in vitro. Reaction requirements and inhibitor sensitivities were the same as those of phosphotyrosine phosphatases (PTPases). Analysis of cdc25 C-terminal domains from a variety of species revealed a conserved motif having critical residues present at the active site of PTPases. Mutation of the cdc25 Cys480 codon, corresponding to an essential cysteine in the active site of PTPases, abolished the phosphatase activity of GST-cdc25. These data indicate that cdc25 proteins define a novel subclass of eukaryotic PTPases, and strongly argue that cdc25 proteins directly dephosphorylate and activate p34cdc2 kinase to induce M-phase.     

Cyclin B targets p34cdc2 for tyrosine phosphorylation.

A universal intracellular factor, the 'M phase-promoting factor' (MPF), triggers the G2/M transition of the cell cycle in all organisms. In late G2, it is present as an inactive complex of tyrosine-phosphorylated p34cdc2 and unphosphorylated cyclin Bcdc13. In M phase, its activation as an active MPF displaying histone H1 kinase (H1K) originates from the concomitant tyrosine dephosphorylation of the p34cdc2 subunit and the phosphorylation of the cylin Bcdc13 subunit. We have investigated the role of cyclin in the formation of this complex and the tyrosine phosphorylation of p34cdc2, using highly synchronous mitotic sea urchin eggs as a model. As cells leave the S phase and enter the G2 phase, a massive tyrosine phosphorylation of p34cdc2 occurs. This large p34cdc2 tyrosine phosphorylation burst does not arise from a massive increase in p34cdc2 concentration. It even appears to affect only a fraction (non-immunoprecipitable by anti-PSTAIR antibodies) of the total p34cdc2 present in the cell. Several observations point to an extremely close association between accumulation of unphosphorylated cyclin and p34cdc2 tyrosine phosphorylation: (i) both events coincide perfectly during the G2 phase; (ii) both tyrosine-phosphorylated p34cdc2 and cyclin are not immunoprecipitated by anti-PSTAIR antibodies; (iii) accumulation of unphosphorylated cyclin by aphidicolin treatment of the cells, triggers a dramatic accumulation of tyrosine-phosphorylated p34cdc2; and (iv) inhibition of cyclin synthesis by emetine inhibits p34cdc2 tyrosine phosphorylation without affecting the p34cdc2 concentration. These results show that, as it is synthesized, cyclin B binds and recruits p34cdc2 for tyrosine phosphorylation; this inactive complex then requires the completion of DNA replication before it can be turned into fully active MPF. These results fully confirm recent data obtained in vitro with exogenous cyclin added to cycloheximide-treated Xenopus egg extracts.     

Staurosporine is a potent inhibitor of p34cdc2 and p34cdc2-like kinases.

We previously demonstrated that nontransformed cells arrest in the G1 phase of the cell cycle when treated with low concentrations (21 nM) of staurosporine (1). Both normal and transformed cells are blocked in the G2 phase of the cell cycle when treated with higher concentrations (160 nM) of staurosporine (1,2). In the present study, we show that staurosporine inhibits the activity of fractionated p34cdc2 and p34cdc2-like kinases with IC50 values of 4-5 nM. We propose that the G2 phase arrest in the cell cycle caused by staurosporine is due, at least in part, to the inhibition of the p34cdc2 kinases.     

Pre-MPF is absent in immature oocytes of fishes and amphibians except Xenopus

Maturation-promoting factor (MPF), a final trigger for initiating oocyte maturation, is activated in the oocyte cytoplasm, in response to maturation-inducing hormone (MIH) secreted from follicle cells surrounding the oocyte. MPF consists of cdc2 and cyclin B. We investigated the state of cdc2 and cyclin B in immature and mature oocytes of fishes (carp, catfish and lamprey) and amphibians ( Xenopus, frog [ Rana ] and toad [ Bufo ]) using monoclonal antibodies raised against mouse cdc2, which also recognize fish and amphibian cdc2, and monoclonal antibodies against goldfish cyclin B1 and polyclonal antibodies against Xenopus cyclins B1 and B2. Anti-cdc2 and anti-cyclin B immunoblotting of oocyte extracts fractionated by gel filtration chromatography showed that immature oocytes from all of these species with the exception of Xenopus contained only monomeric cdc2. Cyclin B-bound inactive cdc2 (pre-MPF) was present only in immature Xenopus oocytes. Cdc2-cyclin B complex was, however, found in mature oocytes from all the species examined. After the oocyte is induced to mature by MIH, cdc2 should therefore bind to cyclin B in all of these species, except Xenopus. These results suggest that the complex formation of cdc2 and cyclin B in response to MIH stimulation at the oocyte surface is a critical step for initiating oocyte maturation in fishes and amphibians, with the exception of Xenopus , in which pre-MPF already exists in immature oocytes and only its chemical modification is required for MPF activation.     

Coupling of mitosis to the completion of S phase in Xenopus occurs via modulation of the tyrosine kinase that phosphorylates p34cdc2.

In cell-free extracts derived from Xenopus eggs which oscillate between S phase and mitosis, incompletely replicated DNA blocks the activation of p34cdc2-cyclin by maintaining p34cdc2 in a tyrosine-phosphorylated form. We used a recombinant cyclin fusion protein to generate a substrate to measure the ability of the tyrosine kinase(s) to phosphorylate and inactivate p34cdc2 in the absence of tyrosine phosphatase activity. p34cdc2 tyrosine phosphorylation is highly regulated during the cell cycle, being elevated in S phase and attenuated in mitosis. The elevation in p34cdc2 tyrosine phosphorylation rate occurs in response to the presence of incompletely replicated DNA. Moreover, okadaic acid and caffeine, which uncouple the dependence of mitosis on the completion of S phase, increase unphosphorylated p34cdc2 by attenuating tyrosine kinase function. These data indicate that the control system, which monitors the state of DNA replication, modulates the function of the tyrosine kinase by a phosphorylation/dephosphorylation mechanism, ensuring that mitosis occurs only when S phase is complete.     

Reversible tyrosine phosphorylation of cdc2: dephosphorylation accompanies activation during entry into mitosis

Tyrosine phosphorylation of cdc2 is regulated in the cell cycle of mouse 3T3 fibroblasts. Phosphotyrosine in cdc2 is detectable at the onset of DNA synthesis and becomes maximal in the G2 phase of the cell cycle. Quantitative tyrosine dephosphorylation of cdc2 occurs during entry into mitosis and no phosphotyrosine is detected during the G1 phase of the cell cycle. While increasing tyrosine phosphorylation of cdc2 correlates with the formation of a cdc2/p62 complex, the tyrosine phosphorylated cdc2 is inactive as a histone H1 kinase. cdc2 is fully dephosphorylated in its most active mitotic form, yet specific tyrosine dephosphorylation of interphase cdc2 in vitro is insufficient to activate the kinase. In vivo inhibition of tyrosine dephosphorylation by exposure of cells to a phosphatase inhibitor is associated with G2 arrest, which is reversible upon the removal of the phosphatase inhibitor. Tyrosine dephosphorylation of cdc2 may be one of a number of obligatory steps in the mitotic activation of the kinase.     

Effect of oocyte diameter on meiotic competence, embryo development, p34 (cdc2) expression and MPF activity in prepubertal goat oocytes

The aim of this study was to analyze the relationship between oocyte diameter, meiotic and embryo developmental competence and the expression of the catalytic subunit of MPF, the p34(cdc2), at mRNA, RNA and protein level, as well as its kinase activity, in prepubertal (1-2 months old) goat oocytes. MPF is the main meiotic regulator and a possible regulator of cytoplasmic maturation; therefore, it could be a key factor in understanding the differences between competent and incompetent oocytes. Oocytes were classified according to oocyte diameter in four categories: <110, 110-125, 125-135 and >135 microm and matured, fertilized and cultured in vitro. The p34(cdc2) was analyzed in oocytes at the time of collection (0 h) and after 27 h of IVM (27 h) in each of the oocyte diameter categories. The oocyte diameter was positively related to the percentage of oocytes at MII after IVM (0, 20.7, 58 and 78%, respectively) and the percentage of blastocysts obtained at 8 days postinsemination (0, 0, 1.95 and 12.5%, respectively). The expression of RNA and mRNA p34(cdc2) did not vary between oocyte diameters at 0 and 27h. Protein expression of p34(cdc2) increased in each oocyte category after 27 h of maturation. MPF activity among diameter groups did not vary at 0h but after IVM there was a clear and statistically significant increase of MPF activity in the biggest oocytes.     

MPF from starfish oocytes at first meiotic metaphase is a heterodimer containing one molecule of cdc2 and one molecule of cyclin B.

We have purified to near homogeneity the M-phase-specific protein kinase from starfish oocytes at first meiotic metaphase, using an improved procedure based on affinity chromatography on the immobilized yeast protein suc1. As already reported, this is identical to MPF, the cytoplasmic factor that controls entry of eukaryotic cells into M-phase. MPF is a complex formed by the stoichiometric association of a 34-kd polypeptide previously identified as cdc2 with a polypeptide that migrates with the same mobility as starfish cyclin in SDS-PAGE (apparent mol. wt 47 kd). A cDNA clone encoding starfish cyclin B has been isolated and its sequence determined. It contains a single open reading frame encoding a predicted 43 729-dalton protein. Partial microsequencing of the 47-kd polypeptide component of MPF allowed its identification as the starfish cyclin. Since the apparent mol. wt of native starfish MPF was found to be less than 100 kd, it is a heterodimer comprising one molecule of cdc2 and one molecule of cyclin B.     

Cell cycle-regulated degradation of Xenopus cyclin B2 requires binding to p34cdc2.

The protein kinase activity of the cell cycle regulator p34cdc2 is inactivated when the mitotic cyclin to which it is bound is degraded. The amino (N)-terminus of mitotic cyclins includes a conserved "destruction box" sequence that is essential for degradation. Although the N-terminus of sea urchin cyclin B confer cell cycle-regulated degradation to a fusion protein, a truncated protein containing only the N-terminus of Xenopus cyclin B2, including the destruction box, is stable under conditions where full length molecules are degraded. In an attempt to identify regions of cyclin B2, other than the destruction box, involved in degradation, the stability of proteins encoded by C-terminal deletion mutants of cyclin B2 was examined in Xenopus egg extracts. Truncated cyclin with only the first 90 amino acids was stable, but other C-terminal deletions lacking between 14 and 187 amino acids were unstable and were degraded by a mechanism that was neither cell cycle regulated nor dependent upon the destruction box. None of the C-terminal deletion mutants bound p34cdc2. To investigate whether the binding of p34cdc2 is required for cell cycle-regulated degradation, the behavior of proteins encoded by a series of full length Xenopus cyclin B2 cDNA with point mutations in conserved amino acids in the p34cdc2-binding domain was examined. All of the point mutants failed to form stable complexes with p34cdc, and their degradation was markedly reduced compared to wild-type cyclin. Similar results were obtained when the mutant cyclins were synthesized in reticulocyte lysates and when cyclin mRNA was translated directly in a Xenopus egg extract. These results indicate that mutations that interfere with p34cdc2 binding also interfere with cyclin destruction, suggesting that p34cdc2 binding is required for the cell cycle-regulated destruction of Xenopus cyclin B2.     

Cytokinin controls the cell cycle at mitosis by stimulating the tyrosine dephosphorylation and activation of p34cdc2-like H1 histone kinase

In excised pith parenchyma from Nicotiana tabacum L. cv. Wisconsin Havana 38, auxin (naphthalene-1-acetic acid) together with cytokinin (6-benzylaminopurine) induced a greater than 40-fold increase in a p34^cdc2-like protein, recoverable in the p13^suc1-binding fraction, that had high H1 histone kinase activity, but enzyme induced without cytokinin was inactive. In suspension-cultured N. plumbaginifolia Viv., cytokinin (kinetin) was stringently required only in late G2 phase of the cell division cycle (cdc) and cells lacking kinetin arrested in G2 phase with inactive p34^cdc2-like H1 histone kinase. Control of the Cdc2 kinase by inhibitory tyrosine phosphorylation was indicated by high phosphotyrosine in the inactive enzyme of arrested pith and suspension cells. Yeast cdc25 phosphatase, which is specific for removal of phosphate from tyrosine at the active site of p34^cdc2 enzyme, was expressed in bacteria and caused extensive in-vitro activation of p13^suc1-purified enzyme from pith and suspension cells cultured without cytokinin. Cytokinin stimulated the removal of phosphate, activation of the enzyme and rapid synchronous entry into mitosis. Therefore, plants can control cell division by tyrosine phosphorylation of Cdc2 but differ from somatic animal cells in coupling this mitotic control to hormonal signals.Abbreviations BAP 6-benzylaminopurine - BrdUrd 5-bromo-2-deoxyuridine - cdc cell division cycle - Cdc25 cdc phospho-protein phosphatase - CKI cyclin dependent kinase inhibitor - 2,4-D 2,4-dichlorophenoxyacetic acid - DAPI 4,6 diamidino-2-phenylindole - GST-cdc25 glutathione sulfur transferase-truncated cdc25 fusion - MS Murashige and Skoog (1962) - NAA naphthalene-1-acetic acid - p34^cdc2 34-kDa product of the cdc2 gene     

Dissociation of MAP kinase activation and MPF activation in hormone-stimulated maturation of Xenopus oocytes.

MAP kinase activation occurs during meiotic maturation of oocytes from all animals, but the requirement for MAP kinase activation in reinitiation of meiosis appears to vary between different classes. In particular, it has become accepted that MAP kinase activation is necessary for progesterone-stimulated meiotic maturation of Xenopus oocytes, while this is clearly not the case in other systems. In this paper, we demonstrate that MAP kinase activation in Xenopus oocytes is an early response to progesterone and can be temporally dissociated from MPF activation. We show that MAP kinase activation can be suppressed by treatment with geldanamycin or by overexpression of the MAP kinase phosphatase Pyst1. A transient and low-level early activation of MAP kinase increases the efficiency of cell cycle activation later on, when MAP kinase activity is no longer essential. Many oocytes can still undergo reinitiation of meiosis in the absence of active MAP kinase. Suppression of MAP kinase activation does not affect the formation or activation of Cdc2-cyclin B complexes, but reduces the level of active Cdc2 kinase. We discuss these findings in the context of a universal mechanism for meiotic maturation in oocytes throughout the animal kingdom.