The Bub2-dependent mitotic pathway in yeast acts every cell cycle and regulates cytokinesis.

In eukaryotes an abnormal spindle activates a conserved checkpoint consisting of the MAD and BUB genes that results in mitotic arrest at metaphase. Recently, we and others identified a novel Bub2-dependent branch to this checkpoint that blocks mitotic exit. This cell-cycle arrest depends upon inhibition of the G-protein Tem1 that appears to be regulated by Bfa1/Bub2, a two-component GTPase-activating protein, and the exchange factor Lte1. Here, we find that Bub2 and Bfa1 physically associate across the entire cell cycle and bind to Tem1 during mitosis and early G1. Bfa1 is multiply phosphorylated in a cell-cycle-dependent manner with the major phosphorylation occurring in mitosis. This Bfa1 phosphorylation is Bub2-dependent. Cdc5, but not Cdc15 or Dbf2, partly controls the phosphorylation of Bfa1 and also Lte1. Following spindle checkpoint activation, the cell cycle phosphorylation of Bfa1 and Lte1 is protracted and some species are accentuated. Thus, the Bub2-dependent pathway is active every cell cycle and the effect of spindle damage is simply to protract its normal function. Indeed, function of the Bub2 pathway is also prolonged during metaphase arrests imposed by means other than checkpoint activation. In metaphase cells Bub2 is crucial to restrain downstream events such as actin ring formation, emphasising the importance of the Bub2 pathway in the regulation of cytokinesis. Our data is consistent with Bub2/Bfa1 being a rate-limiting negative regulator of downstream events during metaphase.

The budding yeast Dbf2 protein kinase localises to the centrosome and moves to the bud neck in late mitosis.

Dbf2 is a multifunctional protein kinase in Saccharomyces cerevisiae that functions in transcription, the stress response and as part of a network of genes in exit from mitosis. By analogy with fission yeast it seemed likely that these mitotic exit genes would be involved in cytokinesis. As a preliminary investigation of this we have used Dbf2 tagged with GFP to examine intracellular localisation of the protein in living cells. Dbf2 is found on the centrosomes/spindle pole bodies (SPBs) and also at the bud neck where it forms a double ring. The localisation of Dbf2 is cell cycle regulated. It is on the SPBs for much of the cell cycle and migrates from there to the bud neck in late mitosis, consistent with a role in cytokinesis. Dbf2 partly co-localises with septins at the bud neck. A temperature-sensitive mutant of dbf2 also blocks progression of cytokinesis at 37 degrees C. Following cytokinesis some Dbf2 moves into the nascent bud. Localisation to the bud neck depends upon the septins and also the mitotic exit network proteins Mob1, Cdc5, Cdc14 and Cdc15. The above data are consistent with Dbf2 acting downstream in a pathway controlling cytokinesis.

A Bub2p-dependent spindle checkpoint pathway regulates the Dbf2p kinase in budding yeast.

Exit from mitosis in all eukaroytes requires inactivation of the mitotic kinase. This occurs principally by ubiquitin-mediated proteolysis of the cyclin subunit controlled by the anaphase-promoting complex (APC). However, an abnormal spindle and/or unattached kinetochores activates a conserved spindle checkpoint that blocks APC function. This leads to high mitotic kinase activity and prevents mitotic exit. DBF2 belongs to a group of budding yeast cell cycle genes that when mutated prevent cyclin degradation and block exit from mitosis. DBF2 encodes a protein kinase which is cell cycle regulated, peaking in metaphase-anaphase B/telophase, but its function remains unknown. Here, we show the Dbf2p kinase activity to be a target of the spindle checkpoint. It is controlled specifically by Bub2p, one of the checkpoint components that is conserved in fission yeast and higher eukaroytic cells. Significantly, in budding yeast, Bub2p shows few genetic or biochemical interactions with other members of the spindle checkpoint. Our data now point to the protein kinase Mps1p triggering a new parallel branch of the spindle checkpoint in which Bub2p blocks Dbf2p function.

Budding yeast RSI1/APC2, a novel gene necessary for initiation of anaphase, encodes an APC subunit.

SIC1 is a non-essential gene encoding a CDK inhibitor of Cdc28-Clb kinase activity. Sic1p is involved in both mitotic exit and the timing of DNA synthesis. To identify other genes involved in controlling Clb-kinase activity, we have undertaken a genetic screen for mutations which render SIC1 essential. Here we describe a gene we have identified by this means, RSI1/APC2. Temperature-sensitive rsi1/apc2 mutants arrest in metaphase and are unable to degrade Clb2p, suggesting that Rsi1p/Apc2p is associated with the anaphase promoting complex (APC). This is an E3 ubiquitin-ligase that controls anaphase initiation through degradation of Pds1p and mitotic exit via degradation of Clb cyclins. Indeed, the anaphase block in rsi1/apc2 temperature-sensitive mutants is overcome by removal of PDS1, consistent with Rsi1p/Apc2p being part of the APC. In addition, like our rsi1/apc2 mutations, cdc23-1, encoding a known APC subunit, is also lethal with sic1Delta. Thus SIC1 clearly becomes essential when APC function is compromised. Finally, we find that Rsi1p/Apc2p co-immunoprecipitates with Cdc23p. Taken together, our results suggest that RSI1/APC2 is a subunit of APC.

Is Cdk7/cyclin H/MAT1 the genuine cdk activating kinase in cycling Xenopus egg extracts?

Formation of active cdk (cyclin dependent kinase)/ cyclin kinases involves phosphorylation of a conserved threonine residue in the T loop of the cdk catalytic-subunit by CAK (Cdk Activating Kinase). CAK was first purified biochemically from higher eukaryotes and identified as a trimeric complex containing a cdk7 catalytic subunit, cyclin H and MAT1 (Ménage à trois), a member of the RING finger family. The same trimeric complex is also part of basal transcription factor TFIIH. In budding yeast, the closest homologs of cdk7 and cyclin H, KIN28 and CCL1, respectively, also associate with TFIIH. However, the KIN28/CCL1 complex does not display CAK activity and a distinct protein kinase able to phosphorylate monomeric CDC28 and GST-cdk2 was recently identified, challenging the identification of cdk7 as the physiological CAK in higher eukaryotes. Here we demonstrate that immunodepletion of cdk7 suppresses CAK activity from cycling Xenopus egg extracts, and arrest them before M-phase. We also show that specific translation of mRNAs encoding Xenopus cdk7 and its associated subunits restores CAK activity in cdk7-immunodepleted Xenopus egg extracts. Hence, the cdk7 complex is necessary and sufficient for activation of cdk-cyclin complexes in cycling Xenopus egg extracts.

Rig2, a RING finger protein that interacts with the Kin28/Ccl1 CTD kinase in yeast.

Kin28/Cell, a cyclin-dependent kinase, is essential for the in vivo phosphorylation of the C-terminal domain of the largest subunit of RNA polymerase II in Saccharomyces cerevisiae. In a search for mutations co-lethal with a thermosensitive kin28 mutation, we have identified genes whose products interact functionally with Kin28. In the present work, we have studied a new complementation group of synthetic lethal mutations. The corresponding gene, RIG2, encodes a predicted RING finger protein. Rig2 is likely to be a homolog of MAT1 of higher eukaryotes which forms a ternary complex with MO15(cdk7) and cyclin H. Our genetic data suggest that Rig2 is a component of transcription factor TFIIH. Transcription activity in a rig2-ts mutant is impeded at restrictive temperature. However, none of the rig2-ts mutants obtained was UV sensitive, suggesting that Rig2 is dispensable for nucleotide excision repair.

Interactions of cyclins with cyclin-dependent kinases: a common interactive mechanism.

The formation of cdk-cyclin complexes has been investigated at the molecular level and quantified using spectroscopic approaches. In the absence of phosphorylation, cdk2, cdc2, and cdk7 form highly stable complexes with their "natural" cyclin partners with dissociation constants in the nanomolar range. In contrast, nonphosphorylated cdc2-cyclin H, cdk2-cyclin H, and cdk7-cyclin A complexes present a 25-fold lower stability. On the basis of both the structure of the cdk2-cyclin A complex and on our kinetic results, we suggest that interaction of any cyclin with any cdk involves the same hydrophobic contacts and induces a marked conformational change in the catalytic cleft of the cdks. Although cdks bind ATP strongly, they remain in a catalytically inactive conformation. In contrast, binding of the cyclin induces structural rearrangements which result in the selective reorientation of ATP, a concomitant 3-fold increase in its affinity, and a 5-fold decrease of its release from the active site of cdks.

MAT1 ('menage à trois') a new RING finger protein subunit stabilizing cyclin H-cdk7 complexes in starfish and Xenopus CAK.

The kinase responsible for Thr161-Thr160 phosphorylation and activation of cdc2/cdk2 (CAK:cdk-activating kinase) has been shown previously to comprise at least two subunits, cdk7 and cyclin H. An additional protein co-purified with CAK in starfish oocytes, but its sequencing did not reveal any similarity with any known protein. In the present work, a cDNA encoding this protein is cloned and sequenced in both starfish and Xenopus oocytes. It is shown to encode a new member of the RING finger family of proteins with a characteristic C3HC4 motif located in the N-terminal domain. We demonstrate that the RING finger protein (MAT1: 'menage à trois') is a new subunit of CAK in both vertebrate and invertebrates. However, CAK may also exist in oocytes as heterodimeric complexes between cyclin H and cdk7 only. Stable heterotrimeric CAK complexes were generated in reticulocyte lysates programmed with mRNAs encoding Xenopus cdk7, cyclin H and MAT1. In contrast, no heterodimeric cyclin H-cdk7 complex could be immunoprecipitated from reticulocyte lysates programmed with cdk7 and cyclin H mRNAs only. Stabilization of CAK complexes by MAT1 does not involve phosphorylation of Thr176, as the Thr176-->Ala mutant of Xenopus cdk7 could engage as efficiently as wild-type cdk7 in ternary complexes. Even though starfish MAT1 is almost identical to Xenopus MAT1 in the RING finger domain, the starfish subunit could not replace the Xenopus subunit and stabilize cyclin H-cdk7 in reticulocyte lysate, suggesting that the MAT1 subunit does not (or not only) interact with cyclin H-cdk7 through the RING finger domain.

p40MO15 associates with a p36 subunit and requires both nuclear translocation and Thr176 phosphorylation to generate cdk-activating kinase activity in Xenopus oocytes.

p40MO15, a cdc2-related protein, is the catalytic subunit of the kinase (CAK, cdk-activating kinase) responsible for Thr161/Thr160 phosphorylation and activation of cdk1/cdk2. We have found that strong overexpression of p40MO15 only moderately increases CAK activity in Xenopus oocytes, indicating that a regulatory CAK subunit (possibly a cyclin-like protein) limits the ability to generate CAK activity in p40MO15 overexpressing oocytes. This 36 kDa subunit was microsequenced after extensive purification of CAK activity. Production of Xenopus CAK activity was strongly reduced in enucleated oocytes overexpressing p40MO15 and p40MO15 shown to contain a nuclear localization signal required for nuclear translocation and generation of CAK activity. p40MO15 was found to be phosphorylated on Ser170 and Thr176 by proteolytic degradation, radiosequencing of tryptic peptides and mutagenesis. Thr176 phosphorylation is required and Ser170 phosphorylation is dispensable for p40MO15 to generate CAK activity upon association with the 36 kDa regulatory subunit. Finally, Thr176 and Ser170 phosphorylations are not intramolecular autophosphorylation reactions. Taken together, the above results identify protein-protein interactions, nuclear translocation and phosphorylation (by an unidentified kinase) as features of p40MO15 that are required for the generation of active CAK.

Cloning, expression and subcellular localization of the human homolog of p40MO15 catalytic subunit of cdk-activating kinase.

Transitions of the cell cycle are controlled by cyclin-dependent protein kinases (cdks) whose phosphorylation on the Thr residue included in the conserved sequence YTHEVV dramatically increases the activity. A kinase responsible for this specific phosphorylation, called CAK for cdk-activating kinase, has been recently purified from starfish and Xenopus oocytes and shown to contain the MO15 gene product as a catalytic subunit. In the present paper, we have cloned the human homolog of Xenopus p40MO15 by probing a HeLa cell cDNA library with degenerate oligonucleotides deduced from Xenopus and starfish MO15 sequences. Human and Xenopus MO15 displayed a strong homology showing 86% identity with regard to amino acid sequences. Northern blot analysis of RNA extracts from a series of human tissues as well as from cultured rodent fibroblasts revealed a unique 1.4 kb MO15 mRNA. No variation in the amount of MO15 transcript or protein was found along the entire course of the fibroblast cell cycle. Fluorescence in situ hybridization on human lymphocyte metaphases showed two distinct chromosomal locations of human MO15 gene at 5q12-q13 and 2q22-q24. By using gene tagging and mammalian cell transfection, we demonstrate that the KRKR motif located at the carboxy terminal end of MO15 is required for nuclear targeting of the protein. Mutation of KRKR to NGER retains MO15 in the cytoplasmic compartment, whilst the wild-type protein is detected exclusively in the nucleus. Interestingly, we demonstrate that the nuclear targeting of MO15 is necessary to confer the protein its CAK activity. In contrast to the wild-type, the NLS-mutated MO15 expressed in Xenopus oocytes is unable to generate CAK as long as the nuclear envelope is not broken. The nuclear localization of both the MO15 gene product and CAK activity may imply that cdks activation primarily occurs in the cell nucleus.

Nuclear import of the myogenic factor MyoD requires cAMP-dependent protein kinase activity but not the direct phosphorylation of MyoD.

MyoD is a nuclear phosphoprotein that belongs to the family of myogenic regulatory factors and acts in the transcriptional activation of muscle-specific genes. We have investigated the role of cAMP-dependent protein kinase (A-kinase) in modulating the nuclear locale of MyoD. Purified MyoD protein microinjected into the cytoplasm of rat embryo fibroblasts is rapidly translocated into the nucleus. Inhibition of A-kinase activity through injection of the specific inhibitory peptide PKI prevents this nuclear localisation. This inhibition of nuclear location is specifically reversed by injection of purified A-kinase catalytic subunit, showing the requirement for A-kinase in the nuclear import of MyoD. Site-directed mutagenesis of all the putative sites for A-kinase-dependent phosphorylation on MyoD, substituting serine or threonine residues for the non-phosphorylatable amino acid alanine, had no effect on nuclear import of mutated MyoD. These data exclude the possibility that the effect of A-kinase on the nuclear translocation of MyoD is mediated by direct phosphorylation of MyoD and imply that A-kinase operates through phosphorylation of components involved in the nuclear transport of MyoD.

Calmodulin-dependent protein kinase II mediates inactivation of MPF and CSF upon fertilization of Xenopus eggs.

In vertebrates, unfertilized eggs are arrested at second meiotic metaphase by a cytostatic factor (CSF), an essential component of which is the product of the c-mos proto-oncogene. CSF prevents ubiquitin-dependent degradation of mitotic cyclins and thus inactivation or the M phase-promoting factor (MPF). Fertilization or parthenogenetic activation triggers a transient increase in the cytoplasmic free Ca2+ (reviewed in refs 5 and 6), inactivates both CSF and MPF, and releases eggs from meiotic metaphase arrest. A calmodulin-dependent process is required for cyclin degradation to occur in cell-free extracts prepared from metaphase II-arrested eggs (CSF extracts) when the free Ca2+ concentration is transiently raised in the physiological micromolar range. Here we show that when a constitutively active mutant of calmodulin-dependent protein kinase II (CaM KII) is added to a CSF extract, cyclin degradation and Cdc2 kinase inactivation occur even in the absence of Ca2+, and the extract loses its ability to cause metaphase arrest when transferred into embryos. Furthermore, specific inhibitors of CaM KII prevent cyclin degradation after calcium addition. Finally, the direct microinjection of constitutively active CaM KII into unfertilized eggs inactivates Cdc2 kinase and CSF, even in the absence of a Ca2+ transient. The target for Ca(2+)-calmodulin is thus CaM KII.

The MO15 gene encodes the catalytic subunit of a protein kinase that activates cdc2 and other cyclin-dependent kinases (CDKs) through phosphorylation of Thr161 and its homologues.

Phosphorylation of Thr161, a residue conserved in all members of the cdc2 family, has been reported to be absolutely required for the catalytic activity of cdc2, the major regulator of eukaryotic cell cycle. In the present work, we have purified from starfish oocytes a kinase that specifically activates cdc2 in a cyclin-dependent manner through phosphorylation of its Thr161 residue. Our most highly purified preparation contained only two major proteins of apparent M(r) 37 and 40 kDa (p37 and p40), which could not be separated from each other without loss of activity. The purified kinase was found to phosphorylate not only cdc2, but also cdk2 and a divergent cdc2-like protein from Caenorhabditis, in chimeric complexes including both mitotic and G1/S cyclins. Extensive microsequencing of p40 did not reveal any convincing homology with any known protein. In contrast, p37 is the starfish homologue of the M015 gene product, a kinase previously cloned by homology probing from a Xenopus cDNA library. As expected, immunodepletion of the MO15 protein depleted Xenopus egg extracts of CAK (cdk-activating kinase) activity, which was recovered in immunoprecipitates. Taken together, the above results demonstrate that MO15 is a gene conserved throughout evolution (at least from echinoderms to vertebrates) that encodes the catalytic subunit of a protein kinase that activates cdc2-cdks complexes through phosphorylation of Thr161 (or its homologues).

Loss of the G1-S control of cyclin A expression during tumoral progression of Chinese hamster lung fibroblasts.

The expression of cyclin A, one of the key regulators of cell cycle progression in association with cdc2/cdk2 protein kinases and which undergoes cyclic accumulation during the cell cycle, has been investigated in CCL39 Chinese hamster lung fibroblasts and in two transformed variants, A71 and 39Py. Whereas A71 (selected after tumor induction in nude mice) is subject to growth arrest (less than 5% of labeled nuclei after 24 h of serum starvation), 39Py (obtained after transformation by polyoma virus) is not (more than 50% of labeled nuclei). In both cells, cyclin A expression was correlated with establishment of S phase, with a progressive deregulation of its G1 controls. This deregulation was not detected with the two early response genes c-fos and c-myc. The kinetics of accumulation of cyclin A lagged behind that of [3H]thymidine incorporation, thereby questioning a direct role for cyclin A in S phase triggering. Moreover, transforming growth factor beta 1, which is known to inhibit alpha-thrombin or fibroblast growth factor-induced mitogenicity in G0-arrested CCL39 cells, is shown here to down-regulate cyclin A expression in both CCL39 and A71 cells but has no effect on 39Py cells. These data establish cyclin A as a sensitive marker for the loss of growth factor requirement.

Cyclin A potentiates maturation-promoting factor activation in the early Xenopus embryo via inhibition of the tyrosine kinase that phosphorylates cdc2.

We have produced human cyclin A in Escherichia coli and investigated how it generates H1 kistone kinase activity when added to cyclin-free extracts prepared from parthenogenetically activated Xenopus eggs. Cyclin A was found to form a major complex with cdc2, and to bind cdk2/Eg1 only poorly. No lag phase was detected between the time when cyclin A was added and the time when H1 histone kinase activity was produced in frog extracts, even in the presence of 2 mM vanadate, which blocks cdc25 activity. Essentially identical results were obtained using extracts prepared from starfish oocytes. We conclude that formation of an active cyclin A-cdc2 kinase during early development escapes an inhibitory mechanism that delays formation of an active cyclin B-cdc2 kinase. This inhibitory mechanism involves phosphorylation of cdc2 on tyrosine 15. Okadaic acid (OA) activated cyclin B-cdc2 kinase and strongly reduced tyrosine phosphorylation of cyclin B-associated cdc2, even in the presence of vanadate. 6-dimethylamino-purine, a reported inhibitor of serine-threonine kinases, suppressed OA-dependent activation of cyclin B-cdc2 complexes. This indicates that the kinase(s) which phosphorylate(s) cdc2 on inhibitory sites can be inactivated by a phosphorylation event, itself antagonized by an OA-sensitive, most likely type 2A phosphatase. We also found that cyclin B- or cyclin A-cdc2 kinases can induce or accelerate conversion of the cyclin B-cdc2 complex from an inactive into an active kinase. Cyclin B-associated cdc2 does not undergo detectable phosphorylation on tyrosine in egg extracts containing active cyclin A-cdc2 kinase, even in the presence of vanadate. We propose that the active cyclin A-cdc2 kinase generated without a lag phase from neo-synthesized cyclin A and cdc2 may cause a rapid switch in the equilibrium of cyclin B-cdc2 complexes to the tyrosine-dephosphorylated and active form of cdc2 during early development, owing to strong inhibition of the cdc2-specific tyrosine kinase(s). This may explain why early cell cycles are so rapid in many species.

Dephosphorylation of cdc2 on threonine 161 is required for cdc2 kinase inactivation and normal anaphase.

Exit from metaphase of the cell cycle requires inactivation of MPF, a stoichiometric complex between the cdc2 catalytic and the cyclin B regulatory subunits, as well as that of cyclin A-cdc2 kinase. Inactivation of both complexes depends on proteolytic degradation of the cyclin subunit, yet cyclin proteolysis is not sufficient to inactivate the H1 kinase activity of cdc2. Genetic evidence strongly suggests that type 1 phosphatase plays a key role in the metaphase-anaphase transition of the cell cycle. Here we report that inhibition of both type 1 and type 2A phosphatases by okadaic acid allows cyclin degradation to occur, but prevents cdc2 kinase inactivation. Complete inhibition of type 2A phosphatase alone is not sufficient to prevent cdc2 kinase inactivation following cyclin proteolysis. We show further that residue 161 of cdc2 is phosphorylated in active cyclin A or cyclin B complexes at metaphase, whilst unassociated cdc2 is not phosphorylated. Proteolysis of cyclin releases a free cdc2 subunit, which subsequently undergoes dephosphorylation and then migrates more slowly than its Thr161 phosphorylated counterpart in Laemmli gels. Removal of phosphothreonine 161 requires cyclin proteolysis. However, it does not occur even after cyclin proteolysis, when both type 1 and type 2A phosphatases are inhibited. We conclude that both cyclin degradation and dephosphorylation of Thr161 on cdc2, catalysed at least in part by type 1 phosphatase, are required to inactivate either cyclin B- or cyclin A-cdc2 kinases and thus for cells to exit from M phase.

Cyclin A-Cys41 does not undergo cell cycle-dependent degradation in Xenopus extracts.

Truncated cyclin A and cyclin B lacking the N-terminal domain comprising the 'destruction box' escape from proteolysis and arrest cells at metaphase. Mutation of a conserved arginine residue of the destruction domain makes cyclin B resistant to proteolysis. Here we show that mutation of the same residue also makes cyclin A resistant to proteolysis, in either of two situations in which the cyclin degradation pathway is turned on: (i) in Xenopus extracts of activated eggs where the degradation pathway has been permanently turned on by adding a recombinant undegradable cyclin B in which the arginine residue of the destruction box has been substituted by alanine; (ii) in extracts of metaphase II-arrested oocytes after Ca(2+)-dependent inactivation of the cytostatic factor (CSF).

Cyclin A-cdc2 kinase does not trigger but delays cyclin degradation in interphase extracts of amphibian eggs.

Purified cyclin B-cdc2 kinase has been shown previously to trigger cyclin degradation in interphase frog extracts by initiating a cascade of reactions that includes cyclin ubiquitinylation and ends with proteolysis. However, cyclin A-cdc2 kinase was not assayed in these early experiments. Here we have shown that full-length recombinant human cyclin A failed to induce cyclin degradation when it was added to frog extracts free of cyclin B, although it formed an active kinase complex with Xenopus cdc2. A highly purified kinase complex containing a truncated human cyclin A and starfish cdc2 also failed to switch on the cyclin degradation pathway. In contrast, both recombinant cyclin B and highly purified cyclin B-cdc2 kinase readily triggered degradation of both cyclins B and A in frog extracts. Whilst free cyclin A had no inhibitory effect, cyclin A-cdc2 kinase delayed degradation of both cyclins A and B induced by cyclin B-cdc2 kinase. The finding that cyclin A-cdc2 kinase cannot turn on, and even delays, cyclin destruction may be essential to prevent premature inactivation of MPF (maturation-promoting factor) before complete condensation of chromosomes and formation of the metaphase spindle.

Cyclin A is required in S phase in normal epithelial cells.

We have investigated cyclin A expression in a primary culture of normal rat hepatocytes and during rat liver regeneration after partial hepatectomy. In both cases, cyclin A mRNA and protein accumulate as the cells enter S phase. To investigate the potential implication of cyclin A accumulation at S phase, we microinjected anti-sense DNA constructs for cyclin A, resulting in effective inhibition of S phase entry. These effects were specific for cyclin A since anti-sense cyclin B construct had no similar effects. These results therefore, obtained in normal epithelial cells, indicate that cyclin A is involved in S phase and thus should not be only considered as a mitotic cyclin.

Degradation of the proto-oncogene product p39mos is not necessary for cyclin proteolysis and exit from meiotic metaphase: requirement for a Ca(2+)-calmodulin dependent event.

Exit from M phase, which requires cyclin degradation, is prevented from occurring in unfertilized eggs of vertebrates arrested at second meiotic metaphase due to a cytostatic factor recently identified as p39mos, the product of the proto-oncogene c-mos. Calpain can destroy both p39mos and cyclin in vitro in extracts prepared from metaphase-arrested Xenopus eggs, but only when free Ca2+ concentration is raised to the millimolar range. When free Ca2+ concentration is raised for only 30 s to the micromolar range, as occurs in physiological conditions after fertilization, cyclin degradation is induced, byt p39mos is not degraded. Cyclin proteolysis at micromolar free Ca2+, is not inhibited by calpastatin, and therefore does not involve calpain. A cyclin mutant modified in the destruction box is found to be resistant at micromolar, but not millimolar free Ca2+, suggesting that the ubiquitin pathway mediates cyclin degradation at micromolar Ca2+ concentration whereas calpain is involved at the millimolar level. A synthetic peptide which binds Ca(2+)-calmodulin with high affinity suppresses cyclin degradation at micromolar but not millimolar free Ca2+, and this only when it is present in the extract during the first 30 s after raising free Ca2+ concentration. The inhibition of the cyclin degradation pathway by the Ca(2+)-calmodulin binding peptide can be overcome by adding calmodulin. These results strongly suggest that a Ca(2+)-calmodulin process is required as an early event following fertilization to release the cyclin degradation pathway from inhibition in metaphase-arrested eggs. In contrast, p39mos degradation is not required.