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     

Mutation at the CK2 phosphorylation site on Cdc28 affects kinase activity and cell size in Saccharomyces cerevisiae

We have recently reported that protein kinase CK2 phosphortylates both in vivo and in vitro residue serine-46 of the cell cycle regulating protein Cdc28 of budding yeast Saccharomyces cerevisiae, confirming a previous observation that the same site is phosphorylated in Cdc2/Cdk1, the human homolog of Cdc28. In addition, S. cerevisiae in which serine-46 of Cdc28 has been mutated to alanine show a decrease of 33% in both cell volume and protein content, providing the genetic evidence that CK2 is involved in the regulation of budding yeast cell division cycle, and suggesting that this regulation may be brought about in G1 phase of the mammalian cell cycle. Here, we extended this observation reporting that the mutation of serine-46 of Cdc28 to glutamic acid doubles, at least in vitro, the H1-kinase activity of the Cdc28/cyclin A complex. Since this mutation has only little effects on the cell size of the cells, we hypothesize multiple roles of yeast CK2 in regulating the G1 transition in budding yeast.     

Phorbol Ester TPA Rapidly Prevents Activation of p34 Histone H1 Kinase and Concomitantly the Transition from G2 Phase to Mitosis in Synchronized HeLa Cells

HeLa cells in G2 phase are temporarily inhibited and prevented from entering mitosis by treatment with the phorbol ester TPA (12-O-tetradecanoylphorbol-13-acetate), whereas cells in mitosis are refractory to TPA and divide. In this study the possibility was tested that TPA may interfere with the regulatory cycle of MPF (mitosis promoting factor), the rate-limiting protein kinase for cell division. MPF, consisting of the catalytic subunit p34^cdc2 and the regulatory subunit Cyclin B, is known to be activated at the transition from G2 phase to mitosis through dephosphorylation at Tyr¹⁵ and to become inactivated after metaphase by proteolysis. Treatment of HeLa cells (synchronized around the G2-M transition) with TPA (10^-7M) has now been shown to induce an overall decrease of the histone H1 kinase activity associated with anti-p34^cdc2 immunoprecipitates after about 20 to 30 min. In metaphase cells, the histone H1 kinase activity of p34^cdc2 was shown to remain unaffected by TPA treatment. In cultures enriched in G2 cells neither the amount of p34^cdc2 protein nor that of Cyclin B was influenced by TPA. Moreover, the p34^cdc2/Cyclin B complex formation was also unaffected. However, p34^cdc2 from cultures treated with TPA was more intensely stained by anti-phosphotyrosine antibodies than that of control cells, indicating that TPA treatment probably prevented the tyrosine dephosphorylation required for expression of the histone H1 kinase activity of the complex. The results indicate that TPA treatment of HeLa cultures rapidly stops the G2-M transition because it very rapidly prevents the p34^cdc2/Cyclin B complex in G2 cells from developing histone H1 kinase activity.     

A Detailed Study of the Complex Cell Cycle of the Dinoflagellate Crypthecodinium cohnii Biecheler and Evidence for Variation in Histone H1 Kinase Activity

ABSTRACT By adding the protein synthesis inhibitor, emetine (10^-4 M) to a highly synchronized population of Crypthecodinium cohnii Biecheler 1938 at different phases of its cycle, we were able to determine: 1. The existence and the lengthening of the G2-Phase (30 min) in the first cycle (cycle with swimming G1 phase). 2. The time of the second cell cycle phases (cycle in the cyst): G1, 30 min; S, 1.5 h; G2, 2 h and M, 2 h. These results, together with the estimation of the cell volume of the two and four swimming daughter cells emerging from the cysts, allowed us to state the existence of two transition points: G1/S and G2/M, which are necessary for completion of mitosis. We completed this refined approach of the cell cycle in studying the activities of the histone H1 kinase either in dividing or in non-dividing Crypthecodinium cohnii cells with either total soluble proteins or the isolated mitotic kinase complex. The H1 kinase activity of this purified complex is noticeably higher (twice as high) in the dividing cells than in the non-dividing ones. These data are discussed in the light of the basic characteristics of the dinokaryon, and also compared with recent biochemical observations on the same organism and studies on other higher eukaryotic protists and metazoa.     

Expression of the murine homologue of the cell cycle control protein p34cdc2 in T lymphocytes.

The mammalian homologue of the cdc2 gene of the fission yeast Schizosaccharomyces pombe encodes a p34cdc2 cyclin-dependent kinase that regulates the cell cycle of a wide variety of cell types. Resting murine T lymphocytes contained no detectable p34cdc2 protein, histone kinase activity, or specific mRNA for the cdc2 gene. Activation of the T cells by immobilized anti-CD3 resulted in the expression of specific mRNA late in the G1 phase of the cell cycle, and p34cdc2 protein was detectable at or near G1/S. At this point in the cell cycle, the protein was phosphorylated at tyrosine and displayed no H1 histone kinase activity. As the cells progressed through the cycle, the amount of specific mRNA and p34cdc2 increased, and H1 histone kinase activity was detectable when the cells were blocked at G2/M by nocodazole. The activation of T cells by phorbol dibutyrate induced the expression of IL-2R but failed to induce the synthesis of IL-2 or the expression of cdc2-specific mRNA. Under these conditions, the activated cells failed to enter the S phase of the cell cycle. Because the presence of IL-2 added exogenously during activation by phorbol dibutyrate resulted in the expression of cdc2-specific mRNA and progression through the cell cycle, either IL-2 or the interaction with IL-2R may be involved in the expression of cdc2 and regulation of the G1/S transition.     

Cell cycle reentry of mammalian fibroblasts is accompanied by the sustained activation of P44mapk and P42mapk isoforms in the G1 phase and their inactivation at the G1/s transition

Mitogen-activated protein (MAP) kinases are serine/threonine kinases that are rapidly activated in response to mitogenic stimuli. Here we examined the enzymatic activity and phosphorylation state of the individual p44^mapk and p42^mapk isoforms during early G1 and late G1 phase of the mammalian cell cycle. Release of fibroblast cells from early G1 block was accompanied by a rapid rise in the myelin basic protein (MBP) kinase activity of p44^mapk and p42^mapk, which declined slowly over several hours to reach negligible values as cells enter S phase. When cells were released from late G1 block, the activity of p44^mapk and p42^mapk increased transiently, and then rapidly declined to baseline values during G1 to S phase transition. Cells released at the G1/S boundary in a medium lacking growth factors entered S phase in the complete absence of MAP kinase activity. Unlike MAP kinases, the histone H1 kinase activity of p33^cdk2 was elevated in late G1-arrested cells and continued to increase during S phase entry. The enzymatic activation of p44^mapk and p42^mapk in both early G1 and late G1 phase was accompanied by an increase in the phosphothreonine and phosphotyrosine content of the proteins. These findings suggest that the sustained activation of MAP kinases during G1 progression and their inactivation at the G1/S transition are two regulatory processes involved in the mitogenic response to growth factors. © 1995 Wiley-Liss, Inc.     

Exogenous auxin and cytokinin dependent activation of CDKs and cell division in leaf protoplast-derived cells of alfalfa

Alfalfa leaf protoplast cultures were used to study the role ofexogenously supplied auxin and cytokinin on the level and activity ofCdc2-related protein kinases and progression through the first celldivision cycle after re-activation of cell division. Among the threealfalfa Cdc2-related kinases studied, the Cdc2MsA/B kinase (PSTAIRE)showed only significant activity during the first four days ofprotoplast culture while the Cdc2MsD (PPTALRE) and Cdc2MsF kinases(PPTTLRE) exhibited only low or undetectable activity, respectively,during this period. Although the Cdc2MsA/B protein could be detectedin leaves and freshly isolated protoplasts in variable amounts, thekinase was never active in these cells. The kinase protein disappearedfrom protoplast-derived cells at the beginning (8h) of culture but itssynthesis re-commenced dependent on the presence of exogenous auxin butnot cytokinin. The cytokinin response of alfalfa protoplast-derivedcells varied significantly in different experiments although cytokininwas always required for completion of the first cell division cycle.Frequently both auxin and cytokinin was required for DNA replication asnot more than 5% of cells could incorporate BrdU into their DNAduring three days and significant Cdc2MsA/B activity could not bedetected in the absence of exogenous cytokinin. In other protoplastpopulations, the Cdc2MsA/B kinase was activated by auxin alone andallowed the protoplast-derived cells to enther the S-phase at a similarrate observed in parallel cultures with both auxin and cytokinin. Evenin these cultures, however, ca. 95% of the protoplast-derivedcells were arrested before mitosis without exogenous cytokinin supplywhich could be correlated with decreasing Cdc2MsA/B activity. Theseobservations suggest, that although cytokinin is required for bothG0-G1/S and G2/M cell cycle transitions, in certain cultures theG1/S requirement is overcome by some unknown factors (e.g.conditions of explants; endogenous cytokinins etc.). Furthermore, ourexperiments indicate, that the roles of cytokinin are related to thepost-translational regulation of the Cdc2MsA/B kinase complex atboth cell cycle transition points in alfalfa leaf protoplast-derivedcells. Finally, as a marker for the transition from the differentiated(G0) stage to the activated (G1) stage, we suggest using the parametersof nuclear morphology (size and ratio ofnucleus/nucleolus).     

PKN Activation via Transforming Growth Factor-β1 (TGF-β1) Receptor Signaling Delays G2/M Phase Transition in Vascular Smooth Muscle Cells

The transition of vascular smooth muscle cells (VSMCs) from G2 phase into the M (mitosis) phase of the cell cycle is a tightly controlled process. As an arterial SMC prepares for a G2/M transition, the cell has primed the Cdc2/cyclinB1 complex for activation by the phosphorylation of threonine-161 residue on Cdc2. This phosphorylation is necessary but not sufficient for the VSMC to enter into the M phase. In order to enter into mitosis, a phosphatase, Cdc25C, must first dephosphorylate two other critical residues: tyrosine-15 and threonine-14. If Cdc25C phosphatase activity is blocked, VSMC entry into mitosis is delayed. However, how the activity of Cdc25C is regulated has not been fully illustrated.In an earlier published study we have demonstrated that exposure of the VSMC line, PAC-1, to Transforming growth factor-β1 (TGF-β1), activated PKN (a RhoA-dependent kinase). Here we show that exposure to TGF-β1 delays the G2/M transition by 2 hrs in G1/S synchronized and released PAC-1 culture. This delay is abolished by the RhoA kinase inhibitors, HA1077 or Y-27632. More importantly, RNAi knockdown of PKN expression prevents the G2/M transition delay induced by TGF-β1. Changes in PKN activity temporally correlates to the G2/M transition timing. Moreover, Cdc25C is phosphorylated by the TGF-β1-activated PKN. PKN and Cdc25C coimmunoprecipitate with each other. Finally, PKN and Cdc25C co-localize to the nuclear region only during the critical period of time prior to entry into the M phase. Our data demonstrate that Cdc25C activity is negatively regulated by TGF-β1-stimulated PKN. Once activated through TGF-β1 signaling, PKN binds to and phosphorylates Cdc25C. The physical interaction and phosphorylation result in an inactivation of Cdc25C and delay the VSMC entry into the M stage of the cell cycle.     

The oncogenic serine/threonine kinase Pim-1 directly phosphorylates and activates the G2/M specific phosphatase Cdc25C

The proto-oncogene Pim-1 encodes a serine-threonine kinase which is a downstream effector of cytokine signaling and can enhance cell cycle progression by altering the activity of several cell cycle regulators among them the G1 specific inhibitor p21(Waf), the phosphatase Cdc25A and the kinase C-TAK1. Here, we demonstrate by using biochemical assays that Pim-1 can interact with the phosphatase Cdc25C and is able to directly phosphorylate the N-terminal region of the protein. Cdc25C is functionally related to Cdc25A but acts specifically at the G2/M cell cycle transition point and can be inactivated by C-TAK1-mediated phosphorylation. Immuno-fluorescence experiments showed that Pim-1 and Cdc25C co-localize in the cytoplasm of both epithelial and myeloid cells. We find that phosphorylation by Pim-1 enhances the phosphatase activity of Cdc25C and in transfected cells that are arrested in G2/M by bleomycin, Pim-1 can enhance progression into G1. Therefore, we propose that Pim-1 activates Cdc25C by a direct phosphorylation and can thereby assume the function of a positive cell cycle regulator at the G2/M transition.     

Checkpoint kinase 1 regulates diallyl trisulfide-induced mitotic arrest in human prostate cancer cells

We have shown previously that diallyl trisulfide (DATS), a constituent of processed garlic, inhibits proliferation of PC-3 and DU145 human prostate cancer cells by causing G(2)-M phase cell cycle arrest in association with inhibition of cyclin-dependent kinase 1 activity and hyperphosphorylation of Cdc25C at Ser(216). Here, we report that DATS-treated PC-3 and DU145 cells are also arrested in mitosis as judged by microscopy following staining with anti-alpha-tubulin antibody and 4',6-diamidino-2-phenylindole and flow cytometric analysis of Ser(10) phosphorylation of histone H3. The DATS treatment caused activation of checkpoint kinase 1 and checkpoint kinase 2, which are intermediaries of DNA damage checkpoints and implicated in Ser(216) phosphorylation of Cdc25C. The diallyl trisulfide-induced Ser(216) phosphorylation of Cdc25C as well as mitotic arrest were significantly attenuated by knockdown of check-point kinase 1 protein in both PC-3 and DU145 cells. On the other hand, depletion of checkpoint kinase 2 protein did not have any appreciable effect on G(2) or M phase arrest or Cdc25C phosphorylation caused by diallyl trisulfide. The lack of a role of checkpoint kinase 2 in diallyl trisulfide-induced phosphorylation of Cdc25C or G(2)-M phase cell cycle arrest was confirmed using HCT-15 cells stably transfected with phosphorylation-deficient mutant (T68A mutant) of checkpoint kinase 2. In conclusion, the results of the present study suggest existence of a checkpoint kinase 1-dependent mechanism for diallyl trisulfide-induced mitotic arrest in human prostate cancer cells.     

p34(Cdc2) kinase activity is excluded from the nucleus during the radiation-induced G(2) arrest in HeLa cells

The progression of cells from G(2) into mitosis is blocked by exposure to DNA-damaging agents such as ionizing radiation. This G(2) delay is associated with reduced cyclin B1-specific associated histone H1 kinase activity, increased inhibitory phosphorylation of p34(Cdc2), and depressed cyclin B1 levels in HeLa cells. Induction of cyclin B1 or expression of Cdc2AF, a mutant p34(Cdc2) that lacks the sites of inhibitory phosphorylation, only partially reverses the radiation-associated G(2) delay, although both maneuvers rapidly result in increased histone H1 kinase activity. To account for the persistent G(2) delay in the face of active p34(Cdc2) kinase, we determined the location of the kinase activity. Although p34(Cdc2) was active in the cytoplasm, the nuclear p34(Cdc2) was inactive. Irradiation led to nuclear accumulation of the inactive tyrosine-phosphorylated form of p34(Cdc2), whereas the active form was seen in the cytoplasm. At later times when cells had resumed cell cycle progression, nuclear kinase activity was detectable. These results give evidence of segregation of cytoplasmic and nuclear kinase activity after DNA damage that has the effect of enhancing checkpoint control. Shielding the nucleus from the potentially deleterious effects of kinase activity after DNA damage may help irradiated human cancer cells respond to irradiation.     

Multiple cyclin-dependent kinase complexes and phosphatases control G2/M progression in alfalfa cells

Reversible phosphorylation of proteins by kinases and phosphatases plays a key regulatory role in several eukaryotic cellular functions including the control of the division cycle. Increasing numbers of sequence and biochemical data show the involvement of cyclin-dependent kinases (CDKs) and cyclins in regulation of the cell cycle progression in higher plants. The complexity represented by different types of CDKs and cyclins in a single species such as alfalfa, indicates that multicomponent regulatory pathways control G₂/M transition. A set of cdc2-related genes (cdc2Ms A, B, D and F) was expressed in G₂ and M cells. Phosphorylation assays also revealed that at least three kinase complexes (Cdc2Ms A/B, D and F) were successively active in G₂/M cells after synchronization. Interaction between alfalfa mitotic cyclin (Medsa;CycB2;1) and a kinase partner has been reported previously. The present yeast two-hybrid analyses showed differential interaction between defined D-type cyclins and Cdc2Ms kinases functioning in G₂/M phases. Localization of Cdc2Ms F kinase to the preprophase band (PPB), the perinuclear ring in early prophase, the mitotic spindle and the phragmoplast indicated a pivotal role for this kinase in mitotic plant cells. So far limited research efforts have been devoted to the functions of phosphatases in the control of plant cell division. A homologue of dual phosphatase, cdc25, has not been cloned yet from alfalfa; however tyrosine phosphorylation was indicated in the case of Cdc2Ms A kinase and the p^13suc1-bound kinase activity was increased by treatment of this complex with recombinant Drosophila Cdc25. The potential role of serine/threonine phosphatases can be concluded from inhibitor studies based on okadaic acid or endothall. Endothall elevated the kinase activity of p13^suc1-bound fractions in G₂-phase alfalfa cells. These biochemical data are in accordance with observed cytological abnormalities. The present overview with selected original data outlines a conclusion that emphasizes the complexity of G₂/M regulatory events in flowering plants.     

The Saccharomyces cerevisiae Ptc1 protein phosphatase attenuates G2‐M cell cycle blockage caused by activation of the cell wall integrity pathway

Lack of the yeast Ptc1 Ser/Thr protein phosphatase results in numerous phenotypic defects. A parallel search for high‐copy number suppressors of three of these phenotypes (sensitivity to Calcofluor White, rapamycin and alkaline pH), allowed the isolation of 25 suppressor genes, which could be assigned to three main functional categories: maintenance of cell wall integrity (CWI), vacuolar function and protein sorting, and cell cycle regulation. The characterization of these genetic interactions strengthens the relevant role of Ptc1 in downregulating the Slt2‐mediated CWI pathway. We show that under stress conditions activating the CWI pathway the ptc1 mutant displays hyperphosphorylated Cdc28 kinase and that these cells accumulate with duplicated DNA content, indicative of a G2‐M arrest. Clb2‐associated Cdc28 activity was also reduced in ptc1 cells. These alterations are attenuated by mutation of the MKK1 gene, encoding a MAP kinase kinase upstream Slt2. Therefore, our data show that Ptc1 is required for proper G2‐M cell cycle transition after activation of the CWI pathway.     

Control of the yeast cell cycle is associated with assembly/disassembly of the Cdc28 protein kinase complex

The Saccharomyces cerevisiae gene CDC28 encodes a protein kinase required for progression from G1 to S phase in the cell cycle. We present evidence that the active form of the Cdc28 protein kinase is a complex of approximately 160 kd containing an endogenous substrate, p40, and possibly other polypeptides. This complex phosphorylates p40 and exogenous histone H1 in vitro. Cell cycle arrest during G1 results in inactivation of the protein kinase accompanied by the disassembly of the complex. Furthermore, assembly of the complex is regulated during the cell cycle, reaching a maximum during G1. Partial complexes thought to be intermediates in the assembly process phosphorylate histone H1 but not p40. Addition of soluble factors to these partial complexes in vitro restores p40 phosphorylation and causes the complex to increase to the mature size. A model is presented in which p40 phosphorylation is required during G1 for cells to initiate a new cell cycle.