Calcium/calmodulin-dependent phosphorylation and activation of human Cdc25-C at the G2/M phase transition in HeLa cells

The human tyrosine phosphatase (p54(cdc25-c)) is activated by phosphorylation at mitosis entry. The phosphorylated p54(cdc25-c) in turn activates the p34-cyclin B protein kinase and triggers mitosis. Although the active p34-cyclin B protein kinase can itself phosphorylate and activate p54(cdc25-c), we have investigated the possibility that other kinases may initially trigger the phosphorylation and activation of p54(cdc25-c). We have examined the effects of the calcium/calmodulin-dependent protein kinase (CaM kinase II) on p54(cdc25-c). Our in vitro experiments show that CaM kinase II can phosphorylate p54(cdc25-c) and increase its phosphatase activity by 2.5-3-fold. Treatment of a synchronous population of HeLa cells with KN-93 (a water-soluble inhibitor of CaM kinase II) or the microinjection of AC3-I (a specific peptide inhibitor of CaM kinase II) results in a cell cycle block in G2 phase. In the KN-93-arrested cells, p54(cdc25-c) is not phosphorylated, p34(cdc2) remains tyrosine phosphorylated, and there is no increase in histone H1 kinase activity. Our data suggest that a calcium-calmodulin-dependent step may be involved in the initial activation of p54(cdc25-c).     

Activation of the phosphatase activity of human cdc25A by a cdk2-cyclin E dependent phosphorylation at the G1/S transition.

Progression through the cell cycle is monitored at two major points: during the G1/S and the G2/M transitions. In most cells, the G2/M transition is regulated by the timing of p34cdc2 dephosphorylation which results in the activation of the kinase activity of the cdc2-cyclin B complex. The timing of p34cdc2 dephosphorylation is determined by the balance between the activity of the kinase that phosphorylates p34cdc2 (wee1 in human cells) and the opposing phosphatase (cdc25C). Both enzymes are regulated and it has been shown that cdc25C is phosphorylated and activated by the cdc2-cyclin B complex. This creates a positive feed-back loop providing a switch used to control the onset of mitosis. Here, we show that another member of the human cdc25 family, cdc25A, undergoes phosphorylation during S phase, resulting in an increase of its phosphatase activity. The phosphorylation of cdc25A is dependent on the activity of the cdc2-cyclin E kinase. Microinjection of anti-cdc25A antibodies into G1 cells blocks entry into S phase. These results indicate that the cdc25A phosphatase is required to enter S phase in human cells and suggest that this enzyme is part of an auto-amplification loop analogous to that described at the G2/M transition. We discuss the nature of the in vivo substrate of the cdc25A phosphatase in S phase and the possible implications for the regulation of S phase entry.     

p34cdc2 acts as a lamin kinase in fission yeast

The nuclear lamina is an intermediate filament network that underlies the nuclear membrane in higher eukaryotic cells. During mitosis in higher eukaryotes, nuclear lamins are phosphorylated by a mitosis-specific kinase and this induces disassembly of the lamina structure. Recently, p34cdc2 protein kinase purified from starfish has been shown to induce phosphorylation of lamin proteins and disassembly of the nuclear lamina when incubated with isolated chick nuclei suggesting that p34cdc2 is likely to be the mitotic lamin kinase (Peter, M., J. Nakagawa, M. Dorée, J.C. Labbe, and E.A. Nigg. 1990b. Cell. 45:145-153). To confirm and extend these studies using genetic techniques, we have investigated the role of p34cdc2 in lamin phosphorylation in the fission yeast. As fission yeast lamins have not been identified, we have introduced a cDNA encoding the chicken lamin B2 protein into fission yeast. We report here that the chicken lamin B2 protein expressed in fission yeast is assembled into a structure that associates with the nucleus during interphase and becomes dispersed throughout the cytoplasm when cells enter mitosis. Mitotic reorganization correlates with phosphorylation of the chicken lamin B2 protein by a mitosis-specific yeast lamin kinase with similarities to the mitotic lamin kinase of higher eukaryotes. We show that a lamin kinase activity can be detected in cell-free yeast extracts and in p34cdc2 immunoprecipitates prepared from yeast cells arrested in mitosis. The fission yeast lamin kinase activity is temperature sensitive in extracts and immunoprecipitates prepared from strains bearing temperature-sensitive mutations in the cdc2 gene. These results in conjunction with the previously reported biochemical studies strongly suggest that disassembly of the nuclear lamina at mitosis in higher eukaryotic cells is a consequence of direct phosphorylation of nuclear lamins by p34cdc2.     

Phosphorylation and activation of human cdc25-C by cdc2--cyclin B and its involvement in the self-amplification of MPF at mitosis.

We have investigated the mechanisms responsible for the sudden activation of the cdc2-cyclin B protein kinase before mitosis. It has been found previously that cdc25 is the tyrosine phosphatase responsible for dephosphorylating and activating cdc2-cyclin B. In Xenopus eggs and early embryos a cdc25 homologue undergoes periodic phosphorylation and activation. Here we show that the catalytic activity of human cdc25-C phosphatase is also activated directly by phosphorylation in mitotic cells. Phosphorylation of cdc25-C in mitotic HeLa extracts or by cdc2-cyclin B increases its catalytic activity. cdc25-C is not a substrate of the cyclin A-associated kinases. cdc25-C is able to activate cdc2-cyclin B1 in Xenopus egg extracts and to induce Xenopus oocyte maturation, but only after stable thiophosphorylation. This demonstrates that phosphorylation of cdc25-C is required for the activation of cdc2-cyclin B and entry into M-phase. Together, these studies offer a plausible explanation for the rapid activation of cdc2-cyclin B at the onset of mitosis and the self-amplification of MPF observed in vivo.     

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.     

Dephosphorylation of cdc25-C by a type-2A protein phosphatase: specific regulation during the cell cycle in Xenopus egg extracts.

We have examined the roles of type-1 (PP-1) and type-2A (PP-2A) protein-serine/threonine phosphatases in the mechanism of activation of p34cdc2/cyclin B protein kinase in Xenopus egg extracts. p34cdc2/cyclin B is prematurely activated in the extracts by inhibition of PP-2A by okadaic acid but not by specific inhibition of PP-1 by inhibitor-2. Activation of the kinase can be blocked by addition of the purified catalytic subunit of PP-2A at a twofold excess over the activity in the extract. The catalytic subunit of PP-1 can also block kinase activation, but very high levels of activity are required. Activation of p34cdc2/cyclin B protein kinase requires dephosphorylation of p34cdc2 on Tyr15. This reaction is catalysed by cdc25-C phosphatase that is itself activated by phosphorylation. We show that, in interphase extracts, inhibition of PP-2A by okadaic acid completely blocks cdc25-C dephosphorylation, whereas inhibition of PP-1 by specific inhibitors has no effect. This indicates that a type-2A protein phosphatase negatively regulates p34cdc2/cyclin B protein kinase activation primarily by maintaining cdc25-C phosphatase in a dephosphorylated, low activity state. In extracts containing active p34cdc2/cyclin B protein kinase, dephosphorylation of cdc25-C is inhibited, whereas the activity of PP-2A (and PP-1) towards other substrates is unaffected. We propose that this specific inhibition of cdc25-C dephosphorylation is part of a positive feedback loop that also involves direct phosphorylation and activation of cdc25-C by p34cdc2/cyclin B. Dephosphorylation of cdc25-C is also inhibited when cyclin A-dependent protein kinase is active, and this may explain the potentiation of p34cdc2/cyclin B protein kinase activation by cyclin A. In extracts supplemented with nuclei, the block on p34cdc2/cyclin B activation by unreplicated DNA is abolished when PP-2A is inhibited or when stably phosphorylated cdc25-C is added, but not when PP-1 is specifically inhibited. This suggests that unreplicated DNA inhibits p34cdc2/cyclin B activation by maintaining cdc25-C in a low activity, dephosphorylated state, probably by keeping the activity of a type-2A protein phosphatase towards cdc25-C at a high level.     

Platelet-activating factor- and thrombin-induced stimulation of p34cdc2-cyclin histone H1 kinase activity in platelets.

Numerous studies of cell cycle control in dividing cells have pointed to the central role of a 34-kDa histone H1 kinase (p34cdc2) complexed with regulatory subunits known as cyclins. We now report that p34cdc2-cyclin may also participate in signal transduction in nonproliferating, terminally differentiated cells, in this instance during sheep platelet activation. Immunological evidence for the presence of a p34cdc2 cognant in sheep platelet cytosol was obtained with antipeptide antibodies raised against peptide sequences in the conserved PSTAIRE and C-terminus regions of murine cdc2. The immunoreactive 32-kDa protein was adsorbed onto p13suc1-Sepharose, which selectively binds p34cdc2. A 58-kDa protein that also bound to p13suc1-Sepharose was identified as cyclin A on the basis of its size and immunoreactivity with two different anticyclin peptide antibodies. The p34cdc2-cyclin A complex was regulated during platelet activation. Its histone H1 phosphorylating activity was stimulated 2-fold in p13suc1-Sepharose extracts from platelets that had been exposed to platelet-activating factor or thrombin for 1 min prior to harvesting. Our findings imply that the p34cdc2-cyclin complex may serve alternative functions besides control of cell division.     

Relocation and distinct subcellular localization of p34cdc2-cyclin B complex at meiosis reinitiation in starfish oocytes.

M phase promoting factor (MPF) is a major element controlling entry into the M phase of the eukaryotic cell cycle. MPF is composed of two subunits, p34cdc2 and cyclin B. Using indirect immunofluorescence staining with specific antibody against starfish cyclin B, we monitored the dynamics of the subcellular distribution of MPF during meiosis reinitiation in starfish oocytes. We found that all of the cyclin B is already associated with p34cdc2 in immature oocytes arrested at the G2/M border and that this inactive complex is present exclusively in the cytoplasm. After its activation, part of the p34cdc2-cyclin B complex moves into the germinal vesicle before nuclear envelope breakdown, independently of either microtubules or actin filaments. Thereafter, some part of the complex accumulates in the nucleolus and condensed chromosomes. Another portion of the complex accumulates on meiotic asters and spindles, while the rest is still present throughout the cytoplasm. As these patterns of localization are detected in the detergent-extracted oocytes, we propose at least four distinct subcellular states of the p34cdc2-cyclin B complex: freely soluble, microtubule-associated, detergent-resistant cytoskeleton-associated and chromosome-associated. Thus, in addition to the intramolecular modification of p34cdc2-cyclin B complex, its intracellular relocation plays a key role in promoting the M phase.     

The Xenopus XMAP215 and its human homologue TOG proteins interact with cyclin B1 to target p34cdc2 to microtubules during mitosis

Cytoskeleton reorganization, leading to mitotic spindle formation, is an M-phase-specific event and is controlled by maturation promoting factor (MPF: p34cdc2-cyclinB1 complex). It has previously been demonstrated that the p34cdc2-cyclin B complex associates with mitotic spindle microtubules and that microtubule-associated proteins (MAPs), in particular MAP4, might be responsible for this interaction. In this study, we report that another ubiquitous MAP, TOG in human and its homologue in Xenopus XMAP215, associates also with p34cdc2 kinase and directs it to the microtubule cytoskeleton. Costaining of Xenopus cells with anti-TOGp and anti-cyclin B1 antibodies demonstrated colocalization in interphase cells and also with microtubules throughout the cell cycle. Cyclin B1, TOG/XMAP215, and p34cdc2 proteins were recovered in microtubule pellets isolated from Xenopus egg extracts and were eluted with the same ionic strength. Cosedimentation of cyclin B1 with in vitro polymerized microtubules was detected only in the presence of purified TOG protein. Using a recombinant C-terminal TOG fragment containing a Pro-rich region, we showed that this domain is sufficient to mediate cosedimentation of cyclin B1 with microtubules. Finally, we demonstrated interaction between TOG/XMAP215 and cyclin B1 by co-immunoprecipitation assays. As XMAP215 was shown to be the only identified assembly promoting MAP which increases the rapid turnover of microtubules, the TOG/XMAP215-cyclin B1 interaction may be important for regulation of microtubule dynamics at mitosis.     

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.     

Cell cycle regulation of the p34cdc2 inhibitory kinases.

In cells of higher eukaryotic organisms the activity of the p34cdc2/cyclin B complex is inhibited by phosphorylation of p34cdc2 at two sites within its amino-terminus (threonine 14 and tyrosine 15). In this study, the cell cycle regulation of the kinases responsible for phosphorylating p34cdc2 on Thr14 and Tyr15 was examined in extracts prepared from both HeLa cells and Xenopus eggs. Both Thr14- and Tyr15- specific kinase activities were regulated in a cell cycle-dependent manner. The kinase activities were high throughout interphase and diminished coincident with entry of cells into mitosis. In HeLa cells delayed in G2 by the DNA-binding dye Hoechst 33342, Thr14- and Tyr15-specific kinase activities remained high, suggesting that a decrease in Thr14- and Tyr15- kinase activities may be required for entry of cells into mitosis. Similar cell cycle regulation was observed for the Thr14/Tyr15 kinase(s) in Xenopus egg extracts. These results indicate that activation of CDC2 and entry of cells into mitosis is not triggered solely by activation of the Cdc25 phosphatase but by the balance between Thr14/Tyr15 kinase and phosphatase activities. Finally, we have detected two activities capable of phosphorylating p34cdc2 on Thr14 and/or Tyr15 in interphase extracts prepared from Xenopus eggs. An activity capable of phosphorylating Tyr15 remained soluble after ultracentrifugation of interphase extracts whereas a second activity capable of phosphorylating both Thr14 and Tyr15 pelleted. The pelleted fraction contained activities that were detergent extractable and that phosphorylated p34cdc2 on both Thr14 and Tyr15. The Thr14- and Tyr15-specific kinase activities co-purified through three successive chromatographic steps indicating the presence of a dual-specificity protein kinase capable of acting on p34cdc2.     

cdc25+ encodes a protein phosphatase that dephosphorylates p34cdc2.

To determine how the human cdc25 gene product acts to regulate p34cdc2 at the G2 to M transition, we have overproduced the full-length protein (cdc25Hs) as well as several deletion mutants in bacteria as glutathione-S-transferase fusion proteins. The wild-type cdc25Hs gene product was synthesized as an 80-kDa fusion protein (p80GST-cdc25) and was judged to be functional by several criteria: recombinant p80GST-cdc25 induced meiotic maturation of Xenopus oocytes in the presence of cycloheximide; p80GST-cdc25 activated histone H1 kinase activity upon addition to extracts prepared from Xenopus oocytes; p80GST-cdc25 activated p34cdc2/cyclin B complexes (prematuration promoting factor) in immune complex kinase assays performed in vitro; p80GST-cdc25 stimulated the tyrosine dephosphorylation of p34cdc2/cyclin complexes isolated from Xenopus oocyte extracts as well as from overproducing insect cells; and p80GST-cdc25 hydrolyzed p-nitrophenylphosphate. In addition, deletion analysis defined a functional domain residing within the carboxy-terminus of the cdc25Hs protein. Taken together, these results suggest that the cdc25Hs protein is itself a phosphatase and that it may function directly in the tyrosine dephosphorylation and activation of p34cdc2 at the G2 to M transition.     

INH, a negative regulator of MPF, is a form of protein phosphatase 2A.

MPF, a protein kinase complex consisting of cyclin and p34cdc2 subunits, promotes the G2 to M phase transition in eukaryotic cells. The pathway of activation and inactivation of MPF is not well understood, although there is strong evidence that removal of phosphate from a tyrosine residue on p34cdc2 is part of the activation process. INH was originally identified as an activity that could inhibit the posttranslational activation of a latent form of MPF, called pre-MPF, in immature (G2 phase-arrested) Xenopus oocytes. We have purified INH and demonstrated that it is a form of protein phosphatase 2A. Both INH and the catalytic subunit of protein phosphatase 2A can directly inactivate an isolated p34cdc2-cyclin complex. Both cyclin and p34cdc2 become dephosphorylated; the rate of inactivation closely parallels the removal of phosphate from a specific site on p34cdc2. We propose that INH opposes MPF activation by reversing this critical phosphorylation.     

Cell cycle analysis of the activity, subcellular localization, and subunit composition of human CAK (CDK-activating kinase)

The activity of cyclin-dependent kinases (cdks) depends on the phosphorylation of a residue corresponding to threonine 161 in human p34cdc2. One enzyme responsible for phosphorylating this critical residue has recently been purified from Xenopus and starfish. It was termed CAK (for cdk-activating kinase), and it was shown to contain p40MO15 as its catalytic subunit. In view of the cardinal role of cdks in cell cycle control, it is important to learn if and how CAK activity is regulated during the somatic cell cycle. Here, we report a molecular characterization of a human p40MO15 homologue and its associated CAK activity. We have cloned and sequenced a cDNA coding for human p40MO15, and raised specific polyclonal and monoclonal antibodies against the corresponding protein expressed in Escherichia coli. These tools were then used to demonstrate that p40MO15 protein expression and CAK activity are constant throughout the somatic cell cycle. Gel filtration suggests that active CAK is a multiprotein complex, and immunoprecipitation experiments identify two polypeptides of 34 and 32 kD as likely complex partners of p40MO15. The association of the three proteins is near stoichiometric and invariant throughout the cell cycle. Immunocytochemistry and biochemical enucleation experiments both demonstrate that p40MO15 is nuclear at all stages of the cell cycle (except for mitosis, when the protein redistributes throughout the cell), although the p34cdc2/cyclin B complex, one of the major purported substrates of CAK, occurs in the cytoplasm until shortly before mitosis. The absence of obvious changes in CAK activity in exponentially growing cells constitutes a surprise. It suggests that the phosphorylation state of threonine 161 in p34cdc2 (and the corresponding residue in other cdks) may be regulated primarily by the availability of the cdk/cyclin substrates, and by phosphatase(s).     

Phosphorylation of numatrin and other nuclear proteins by cdc2 containing CTD kinase cdc2/p58

Numatrin is a nuclear matrix phosphoprotein whose synthesis and abundance were shown to be regulated during the cell cycle in mitogen-stimulated lymphocytes (Feuerstein, N., and Mond, J. (1987) J. Biol. Chem. 262, 11389-11397). We examined the effect of (a) CTD-kinase, which contains the cdc2 catalytic component (p34) in a complex with a p58 subunit (cdc2/p58) and (b) the M phase-specific histone H1 kinase, which contains the cdc2 kinase in association with a p62 subunit (cdc2/p62), on phosphorylation of numatrin. We show that both cdc2 kinase complexes can phosphorylate numatrin. However, cdc2/p58 at conditions that caused a similar effect to cdc2/p62 on phosphorylation of histone H1 (dpm/micrograms of substrate/micrograms of enzyme) was found to have a 5-25-fold higher catalytic activity in the phosphorylation of numatrin. Analysis of the tryptic phosphopeptide map of numatrin phosphorylated by these cdc2 kinase complexes showed that both kinase complexes phosphorylated two major identical peptides, but minor additional peptides were differentially phosphorylated by each of these kinases. This indicates that under certain experimental conditions cdc2/p58 and cdc2/p62 may express some differences in their catalytic activity. In vitro phosphorylation by CTD kinase of a whole nuclear protein extract from murine fibroblasts showed that numatrin is the most prominent substrate for CTD kinase in this nuclear extract. CTD kinase cdc2/p58 was found to induce significantly the phosphorylation of five other discrete nuclear substrates. Particularly, two nuclear proteins at 75 kDa/pI approximately 6.5 and 85 kDa/pI approximately 5.3, which were not Coomassie Blue stainable, were found to be markedly phosphorylated by CTD kinase. The results of this study call for further study of the role of CTD kinase cdc2/p58 in the phosphorylation of numatrin under physiological conditions and to further characterization of the other nuclear substrates for CTD kinase.     

Requirement for p34cdc2 kinase is restricted to mitosis in the mammalian cdc2 mutant FT210

The mouse FT210 cell line is a temperature-sensitive cdc2 mutant. FT210 cells are found to arrest specifically in G2 phase and unlike many alleles of cdc2 and cdc28 mutants of yeasts, loss of p34cdc2 at the nonpermissive temperature has no apparent effect on cell cycle progression through the G1 and S phases of the division cycle. FT210 cells and the parent wild-type FM3A cell line each possess at least three distinct histone H1 kinases. H1 kinase activities in chromatography fractions were identified using a synthetic peptide substrate containing the consensus phosphorylation site of histone H1 and the kinase subunit compositions were determined immunochemically with antisera prepared against the "PSTAIR" peptide, the COOH-terminus of mammalian p34cdc2 and the human cyclins A and B1. The results show that p34cdc2 forms two separate complexes with cyclin A and with cyclin B1, both of which exhibit thermal lability at the non-permissive temperature in vitro and in vivo. A third H1 kinase with stable activity at the nonpermissive temperature is comprised of cyclin A and a cdc2-like 34-kD subunit, which is immunoreactive with anti-"PSTAIR" antiserum but is not recognized with antiserum specific for the COOH-terminus of p34cdc2. The cyclin A-associated kinases are active during S and G2 phases and earlier in the division cycle than the p34cdc2-cyclin B1 kinase. We show that mouse cells possess at least two cdc2-related gene products which form cell cycle regulated histone H1 kinases and we propose that the murine homolog of yeast p34cdc/CDC28 is essential only during the G2-to-M transition in FT210 cells.     

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.     

Select Alterations in Protein Kinases and Phosphatases During Apoptosis of Differentiated PC12 Cells

Abstract: The involvement of cell cycle-regulatory proteins in apoptosis of neuronally differentiated PC12 cells induced by the removal of nerve growth factor and serum was examined. Three major findings are presented. (1) Cdc2 kinase protein levels increased fivefold in apoptotic PC12 cells by day 3 of serum and nerve growth factor deprivation. Histone H1 kinase activity was increased significantly in p13^suc1 precipitates of apoptotic PC12 cells, which was due to increased activation and/or expression of cdc2 kinase. (2) The protein levels of cyclin-dependent kinase 4, cyclin D, and proliferating cell nuclear antigen that are normally expressed in the cell cycle were increased during neuronal PC12 cell apoptosis. (3) The levels of the catalytic subunit, but not the regulatory subunit of the calcium/calmodulin-dependent protein phosphatase 2B, decreased significantly concomitant with a significant decrease in protein phosphatase 2B activity early in the apoptotic process. Protein phosphatase 2A activity decreased slightly but significantly after 3 days of serum and nerve growth factor deprivation, and no alterations in protein phosphatase 1 were observed during the apoptotic process. These data demonstrate that certain cell cycle-regulatory proteins are inappropriately expressed and that alterations in specific phosphorylation events, as indicated by the increase in histone H1 kinase activity and the decrease in protein phosphatase 2B activity, are most likely occurring during apoptosis of PC12 cells. These observations support the hypothesis that apoptosis may be due in part to a nondividing cell's uncoordinated attempt to reenter and progress through the cell cycle.