Mitosis-specific phosphorylation of p60c-src by p34cdc2-associated protein kinase

As cells enter mitosis, the protein-tyrosine kinase, p60c-src, is known to be extensively phosphorylated on threonine in its amino-terminal region. In the present work, extracts of mitotic cells were searched for the protein kinase responsible for this phosphorylation. HeLa cells and Xenopus eggs were found to contain a mitosis-specific protein kinase activity capable of phosphorylating highly purified p60c-src in vitro on threonine residues. Tryptic phosphopeptide maps indicate that the mitotic HeLa kinase phosphorylates the same sites in vitro as those used during mitosis in vivo. In addition, this mitotic HeLa kinase comigrates on gel filtration with p34cdc2-associated histone H1 kinase, a well known regulator of mitotic events. Finally, antibodies to the C-terminal peptide of human p34cdc2 specifically deplete p60c-src-phosphorylating activity from mitotic extracts. These results suggest that p60c-src may act as an effector of p34cdc2 in certain mitotic processes.     

Mutations of p34cdc2 phosphorylation sites induce premature mitotic events in HeLa cells: evidence for a double block to p34cdc2 kinase activation in vertebrates.

In vertebrates, entry into mitosis is accompanied by dephosphorylation of p34cdc2 kinase on threonine 14 (Thr14) and tyrosine 15 (Tyr15). To examine the role of these residues in controlling p34cdc2 kinase activation, and hence the onset of mitosis, we replaced Thr14 and/or Tyr15 by non-phosphorylatable residues and transfected wild-type and mutant chicken p34cdc2 cDNAs into HeLa cells. While expression of wild-type p34cdc2 did not interfere with normal cell cycle progression, p34cdc2 carrying mutations at both Thr14 and Tyr15 displayed increased histone H1 kinase activity and rapidly induced premature mitotic events, including chromosome condensation and lamina disassembly. No phenotype was observed in response to mutation of only Thr14, and although single-site mutation at Tyr15 did induce premature mitotic events, effects were partial and their onset was delayed. These results identify both Thr14 and Tyr15 as sites of negative regulation of vertebrate p34cdc2 kinase, and they suggest that dephosphorylation of p34cdc2 represents the rate-limiting step controlling entry of vertebrate cells into mitosis.     

M-phase-specific phosphorylation and structural rearrangement of the cytoplasmic cross-linking protein plectin involve p34cdc2 kinase.

Plectin, a widespread and abundant cytoskeletal cross-linking protein, serves as a target for protein kinases throughout the cell cycle, without any significant variation in overall phosphorylation level. One of the various phosphorylation sites of the molecule was found to be phosphorylated preferentially during mitosis. By in vivo phosphorylation of ectopically expressed plectin domains in stably transfected Chinese hamster ovary cells, this site was mapped to the C-terminal repeat 6 domain of the polypeptide. The same site has been identified as an in vitro target for p34cdc2 kinase. Mitosis-specific phosphorylation of plectin was accompanied by a rearrangement of plectin structures, changing from a filamentous, largely vimentin-associated state in interphase to a diffuse vimentin-independent distribution in mitosis as visualized by immunofluorescence microscopy. Subcellular fractionation studies showed that in interphase cells up to 80% of cellular plectin was found associated with an insoluble cell fraction mostly consisting of intermediate filaments, while during mitosis the majority of plectin (> 75%) became soluble. Furthermore, phosphorylation of purified plectin by p34cdc2 kinase decreased plectin's ability to interact with preassembled vimentin filaments in vitro. Together, our data suggest that a mitosis-specific phosphorylation involving p34cdc2 kinase regulates plectin's cross-linking activities and association with intermediate filaments during the cell cycle.     

Phosphorylation of caldesmon by p34cdc2 kinase. Identification of phosphorylation sites

It has recently been shown that caldesmon from non-muscle (Yamashiro, S., Yamakita, Y., Hosoya, H., and Matsumura, F. (1991) Nature 349, 169-172) and smooth muscle cells (Mak, A. S., Watson, M. H., Litwin, C. M. E., and Wang, J. H. (1991) J. Biol. Chem. 266, 6678-6681) can be phosphorylated in vitro by p34cdc2 kinase resulting in the inhibition of caldesmon binding to F-actin and Ca(2+)-calmodulin. In this study, we have identified five phosphorylation sites in smooth muscle caldesmon at Ser582, Ser667, Thr673, Thr696, and Ser702. All the sites bear some resemblance to the S(T)-P-X-X motif recognized by p34cdc2. The preferred site of phosphorylation at Thr673 accounts for about 40% of the total phosphorylation. Four of the sites occur in two pairs of closely spaced sites, Ser667/Thr673 and Thr696/Ser702; phosphorylation of one site in each pair inhibits strongly the phosphorylation of the second site in the same pair, presumably due to the close proximity of the two sites. Similar negative cooperativity in phosphorylation of Ser667 and Thr673 was observed using a 22-residue synthetic peptide containing the two sites. Phosphorylation of Ser667/Thr673 and Thr696/Ser702 account for about 90% of the total level of phosphorylation and these sites are located within the 10-kDa CNBr fragment at the COOH-terminal end of caldesmon known to bind actin and Ca(2+)-calmodulin.     

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.     

The Arabidopsis functional homolog of the p34cdc2 protein kinase.

The p34cdc2 protein kinase is a key component of the eukaryotic cell cycle, which is required for G1 to S-phase transition and for entry into mitosis. Using a 380-base pair DNA fragment obtained by polymerase chain reaction amplification from an Arabidopsis thaliana flower cDNA library as a probe, we isolated and sequenced a cdc2-homologous cDNA from Arabidopsis. The encoded polypeptide has extensive homology with cdc2-like kinases. Furthermore, when expressed in a CDC28ts Saccharomyces strain, it partially restores the capacity to grow at 36 degrees C, indicating that the plant cDNA is a functional homolog of the p34cdc2 kinase. Genomic hybridization demonstrated that there is one copy of the cdc2 gene per Arabidopsis haploid genome. Using RNA gel blot analysis, we found that cdc2 mRNA is present in all plant organs.     

Role of phosphorylation in p34cdc2 activation: identification of an activating kinase.

Phosphorylation of p34cdc2 can both positively and negatively regulate its kinase activity. We have mapped two phosphorylation sites in Xenopus p34cdc2 to Thr-14 and Tyr-15 within the putative ATP-binding region of p34cdc2. Mutation of these sites to Ala-14 and Phe-15 has no effect on the final histone H1 kinase activity of the cyclin/p34cdc2 complex. Phosphopeptide analysis shows that there is at least one more site of phosphorylation on p34cdc2. When Thr-161 is changed to Ala, two phosphopeptide spots disappear and it is no longer possible to activate the H1 kinase activity of p34cdc2. We suggest that Thr-161 is a third site of phosphorylation, which is required for kinase activity. All three phosphorylations are induced by cyclin. None of the phosphorylations appears to be required for binding to cyclin, as indicated by the ability of the triple mutant, Ala-14, Phe-15, Ala-161, to bind cyclin. The activating phosphorylation that requires Thr- or Ser-161 occurs even in a catalytically inactive K33R mutant of p34cdc2 and hence does not appear to be the result of intramolecular autophosphorylation. We have detected an activity in Xenopus extracts required for activation of p34cdc2 and present evidence that this is a p34cdc2 activating kinase which, in a cyclin-dependent manner, probably directly phosphorylates Thr-161.     

Characterization of synthetic peptide substrates for p34cdc2 protein kinase

Synthetic peptide substrates for the cell division cycle regulated protein kinase, p34cdc2, have been developed and characterized. These peptides are based on the sequences of two known substrates of the enzyme, Simian Virus 40 Large T antigen and the human cellular recessive oncogene product, p53. The peptide sequences are H-A-D-A-Q-H-A-T-P-P-K-K-K-R-K-V-E-D-P-K-D-F-OH (T antigen) and H-K-R-A-L-P-N-N-T-S-S-S-P-Q-P-K-K-K-P-L-D-G-E-Y-NH2 (p53), and they have been employed in a rapid assay of phosphorylation in vitro. Both peptides show linear kinetics and an apparent Km of 74 and 120 microM, respectively, for the purified human enzyme. The T antigen peptide is specifically phosphorylated by p34cdc2 and not by seven other protein serine/threonine kinases, chosen because they represent major classes of such enzymes. The peptides have been used in whole cell lysates to detect protein kinase activity, and the cell cycle variation of this activity is comparable to that measured with specific immune and affinity complexes of p34cdc2. In addition, the peptide phosphorylation detected in mitotic cells is depleted by affinity adsorption of p34cdc2 using either antibodies to p34cdc2 or by immobilized p13, a p34cdc2-binding protein. Purification of peptide kinase activity from mitotic HeLa cells yields an enzyme indistinguishable from p34cdc2. These peptides should be useful in the investigation of p34cdc2 protein kinase and their regulation throughout the cell division cycle.     

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.     

p 34cdc2 kinase homologue in the preprophase band

Summary Immunofluorescence microscopy with a monoclonal antibody raised against the PSTAIR sequence, which corresponds to a peptide conserved in the p 34^cdc2 protein kinase throughout the phylogenetic scale including higher plants, was used to study the intracellular localization of p 34^cdc2 during the cell cycle in onion root tip cells. Although p 34^cdc2 was evenly distributed in the cytoplasm throughout the cell cycle, a more intense staining was observed in the cortical region, where the preprophase band of microtubules (MTs) was located. Double staining with the PSTAIR and plant tubulin antibodies showed that the width of p 34^cdc2 band was narrower than that of MT band. These data raise the interesting question regarding the possible role of p 34^cdc2 protein kinase in determining the division site in plant cells.     

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.     

Association of type II cAMP-dependent protein kinase with p34cdc2 protein kinase in human fibroblasts

Previous independent studies suggested that type II cAMP-dependent protein kinase and the p34cdc2 protein kinase cell cycle regulator co-localize at centrosomes. In order to investigate whether there is an association of type II cAMP-dependent protein kinase with p34cdc2 in human fibroblasts, we used three different approaches. First, the regulatory subunits RI and RII were photoaffinity-labeled with 8-N3-[32P]cAMP, and anti-p34cdc2 immunoprecipitates were screened for the presence of either RI or RII regulatory subunits by one- or two-dimensional gel electrophoresis. Second, anti-RII alpha immunoprecipitates were screened for the presence of p34cdc2 by Western blot using three different affinity-purified antibodies recognizing different domains of human p34cdc2. Conversely, anti-p34cdc2 immunoprecipitates (three different antibodies), as well as the material retained on p13suc1-Sepharose Bio-Beads, which binds specifically p34cdc2, were screened for the presence of RII alpha. Finally, we have looked for cAMP-dependent protein kinase activity specifically inhibited by PKI in immunoprecipitates obtained from extracts treated with different anti-p34cdc2 antibodies. All these experiments gave concordant results and demonstrate that at least at G0/G1, human fibroblasts contain a complex of active type II cAMP-dependent protein kinase associated through its RII alpha subunit with p34cdc2.     

The cdc2-related protein p40MO15 is the catalytic subunit of a protein kinase that can activate p33cdk2 and p34cdc2.

Activation of the cyclin-dependent protein kinases p34cdc2 and p33cdk2 requires binding with a cyclin partner and phosphorylation on the first threonine residue in the sequence THEVVTLWYRAPE. We present evidence that this threonine residue, number 160 in p33cdk2, can be specifically phosphorylated by a cdc2-related protein kinase from Xenopus oocytes called p40MO15. Binding to cyclin A and phosphorylation of this threonine are both required to activate fully the histone H1 kinase activity of p33cdk2. In cell extracts, a portion of p40MO15 is found in a high molecular weight complex that is considerably more active than a lower molecular weight form. Wild-type MO15 protein expressed in bacteria does not possess kinase activity, but acquires p33cdk2-T160 kinase activity after incubation with cell extract and ATP. We conclude that p40MO15 corresponds to CAK (cdc2/cdk2 activating kinase) and speculate that, like p33cdk2 and p34cdc2, p40MO15 requires activation by phosphorylation and association with a companion subunit.     

Activation of p34cdc2 kinase by cyclin A

Functional clam cyclin A and B proteins have been produced using a baculovirus expression system. Both cyclin A and B can induce meiosis I and meiosis II in Xenopus in the absence of protein synthesis. Half-maximal induction occurs at 50 nM for cyclin A and 250 nM for cyclin B. Addition of 25 nM cyclin A to activated Xenopus egg extracts arrested in the cell cycle by treatment with RNase or emetine activates cdc2 kinase to the normal metaphase level and stimulates one oscillatory cell cycle. High levels of cyclin A cause marked hyperactivation of cdc2 kinase and a stable arrest at the metaphase point in the cell cycle. Kinetic studies demonstrate the concentration of cyclin A added does not affect the 10 min lag period required for kinase activation or the timing of maximal activity, but does control the rate of deactivation of cdc2 kinase during exit from mitosis. In addition, exogenous clam cyclin A inhibits the degradation of both A- and B-type endogenous Xenopus cyclins. These results define a system for investigating the biochemistry and regulation of cdc2 kinase activation by cyclin A.     

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.     

p34cdc2 phosphorylation sites in histone H1 are dephosphorylated by protein phosphatase 2A1.

The protein phosphatase activity in rat liver cytosol or nuclear extracts that dephosphorylates histone H1 which has been phosphorylated by p34cdc2 is inhibited completely by okadaic acid, but unaffected by inhibitor-2 or magnesium ions, demonstrating that the only enzyme in this tissue capable of dephosphorylating this substrate is a type 2A phosphatase. Fractionation of the cytosol by anion-exchange chromatography and gel filtration demonstrated that histone H1 phosphatase activity coeluted with the major species of protein phosphatase 2A, termed PP2A1 and PP2A2. PP2A1 was the most active histone H1 phosphatase, its histone phosphatase phosphorylase phosphatase activity ratio being 6-fold higher than PP2A2 and 30-fold higher than the free catalytic subunit PP2AC. It is concluded that PP2A1 is likely to be the enzyme which dephosphorylates p34cdc2-labelled histone H1 in vivo and that the A and B subunits which interact with PP2AC in this species each play a key role in facilitating dephosphorylation of this substrate. The results demonstrate that PP2A, in addition to being involved in suppressing the activation of p34cdc2 in vivo, can also function to reverse at least one of its actions.