Rajnikant Patel

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 G2phase. 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 .

Imaging the spatial dynamics of calmodulin activation during mitosis

BACKGROUND Calcium is an important and ubiquitous signalling ion. In most cell types, changes in intracellular calcium concentrations are sensed by calmodulin, a signal transduction protein that regulates cell function through its interactions with kinases and phosphatases. Calcium signals show complex spatiotemporal patterning, but little, if anything, is known about the patterns of calmodulin activation inside cells. RESULTS We have measured calmodulin activation continuously during mitosis in living cells with a new probe, a fluorescent adduct of calmodulin termed TA-calmodulin. We found that calmodulin was activated locally and episodically in the nucleus and mitotic spindle. The pattern of calmodulin activation was different from the pattern of calcium signals and could not be predicted from the pattern of calcium increase. Calmodulin activation was essential for mitotic progression: both entry into mitosis and exit from mitosis were blocked by a novel peptide that bound to calmodulin with high affinity and so prevented the interaction of calmodulin with its target proteins. CONCLUSIONS These data suggest that calmodulin regulates mitotic transitions and demonstrate the utility of fluorescent adducts for studying protein activation in living cells with good temporal and spatial resolution.

A cyclin-abundance cycle-independent p34cdc2 tyrosine phosphorylation cycle in early sea urchin embryos.

The activity of the cell cycle control protein p34cdc2 is post‐translationally regulated in a variety of cell types. Using anti‐phosphotyrosine antibodies, we find that p34cdc2‐directed tyrosine kinase activity increases at fertilization in sea urchin eggs, leading to a gradual accumulation of phosphotyrosine on p34 during the early part of the cell cycle. Loss of phosphotyrosine from p34 accompanies entry into mitosis and phosphotyrosine reaccumulates as the embryo enters the next cell cycle. A similar pattern is seen when eggs are parthenogenetically activated with ammonium chloride. Tyrosine phosphorylation and phosphorylation/dephosphorylation cycles are suppressed when embryos are treated with the tyrosine kinase inhibitor genistein. On the other hand, a cycle persists when protein synthesis is inhibited with emetine, indicating that it is independent of the synthesis of another class of cell cycle control proteins, the cyclins. Additional experiments with the phorbol ester, phorbol myristate acetate, demonstrate that activating protein synthesis alone in unfertilized eggs does not result in stimulation of p34cdc2 tyrosine kinase activity. Our results indicate that p34 tyrosine phosphorylation cycles are triggered by the fertilization Cai transient. The first cycle is independent of the fertilization pHi signal, confirming that, in sea urchin embryos, the cycle is not tightly coupled to the cycle of cyclin abundance that is a prominent feature of the eukaryotic cell division cycle.

Calcium-induced chromatin condensation and cyclin phosphorylation during chromatin condensation cycles in ammonia-activated sea urchin eggs

Summary Ammonia-activated sea urchin eggs undergo repeated cycles of DNA synthesis, nuclear envelope breakdown (NEB) and chromatin condensation. No mitotic spindle forms, nor do the eggs undergo cytokinesis. Ammonia-activated eggs exhibit a form of the cell cycle in which the nuclear cycle proceeds without segregation of the chromatin into daughter cells. We discuss here experiments that demonstrate that intracellular free calcium concentration controls the S phase–M phase transition in ammonia-activated eggs, as it does in fertilized embryos. Cyclins are proteins that are synthesized throughout the cell cycle and destroyed abruptly during each round of chromatin condensation. We find that cycles of cyclin phosphorylation and destruction occur coincident with chromatin condensation in ammonia-activated eggs. Cyclin phosphorylation also occurs in eggs treated with the tumour promoter, phorbol myristate acetate (PMA). There is no accompanying NEB or chromatin condensation, however, and the nucleus is insensitive to exogenously-generated calcium transients. These latter data indicate that cyclin synthesis and phosphorylation is not a sufficient condition for calcium-induced NEB in sea urchin embryos. PMA must fail to induce one of the necessary cell cycle initiation signals. We suggest that the missing signal is the activation of the cell cycle control protein p34cdc2, which we have shown to be phosphorylated at fertilization and which is phosphorylated in ammonia-activated eggs.

Caffeine overrides the S-phase cell cycle block in sea urchin embryos

During the early mitotic cell cycles of the sea urchin embryo, the cell oscillates between S-phase and M-phase. In the presence of aphidicolin, a DNA synthesis inhibitor, a checkpoint control blocks the activation of the p34cdc2 protein kinase, by keeping it in the inactive, tyrosine phosphorylated form, and the embryos do not enter mitosis. Caffeine has been shown to bypass the G2/M-phase checkpoint in mammalian cells and in cycling Xenopus extracts and to induce mitosis despite the presence of damaged or unreplicated DNA. In this study we show that caffeine also induces mitosis and cell division in sea urchin embryos, in the presence of unreplicated DNA, by stimulating the tyrosine dephosphorylation of p34cdc2 and switching on its protein kinase activity. We also show that the caffeine-induced activation of the p34cdc2 protein kinase is not mediated by either of the two second messengers, calcium and cAMP, or by inhibition of the p34cdc2 tyrosine kinase. Thus, none of the mechanisms proposed for caffeines action can explain how it overrides the S-phase checkpoint in the early cell cycles of the sea urchin embryo.

The cohesin-interacting protein, precocious dissociation of sisters 5A/sister chromatid cohesion protein 112, is up-regulated in human astrocytic tumors.

Glioblastoma multiforme (GBM) is the most prevalent, highly malignant, invasive and difficult-to-treat primary brain tumor in adults. At the genetic level, it is characterized by a high degree of chromosomal instability and aneuploidy. It has been shown that defects in the mitotic spindle checkpoint could lead to the development of aneuploidy as well as tumorigenesis. Additional proteins regulating sister chromatid cohesion could also be involved in maintaining the fidelity of chromosome segregation. One such protein is the precocious dissociation of sisters 5A (Pds5A), also known as sister chromatid cohesion protein 112. It is a nuclear protein, expressed from the S right through to the mitotic phase. It is highly conserved from yeast to man and plays a role in the establishment, maintenance and dissolution of sister chromatid cohesion. The mutation of Pds5A orthologs in lower organisms results in chromosome missegregation, aneuploidy and DNA repair defects. It is considered that such defects can cause either cell death or contribute to the development of cancer cells. Indeed, altered expression levels of Pds5A have been observed in tumors of the breast, kidney, oesophagus, stomach, liver and colon. Malignant gliomas, however, have not been analysed so far. Herein, we report on the cloning of Rattus norvegicus Pds5A and on the analysis of its expression pattern in rat tissue. We also show that Pds5A is significantly overexpressed at both the mRNA and protein level and that this overexpression correlates positively with the WHO grade of human gliomas. However, functional assays show that the siRNA-mediated knockdown of Pds5A affects sister chromatid cohesion but does not influence mitotic checkpoint function or the proliferation and survival of GBM cells. Although the mechanism by which Pds5A functions in GBM cells remains unclear, its overexpression in high grade gliomas implies that it could play a pivotal role during the development and progression of astrocytic tumors.

Growth inhibition by the muscarinic M3 acetylcholine receptor: evidence for p21Cip1/Waf1 involvement in G1 arrest

We have assessed the growth response of Chinese-hamster ovary (CHO) cells to activation of recombinantly expressed G-protein-coupled muscarinic M(2) or M(3) acetylcholine receptors (AChRs). We show that activation of these receptors leads to divergent growth responses: M(2) AChR activation causes an increase in DNA synthesis, whereas M(3) AChR activation causes a dramatic decrease in DNA synthesis. We have characterized the M(3) AChR-mediated growth inhibition and show that it involves a G(1) phase cell-cycle arrest. Further analysis of this arrest indicates that it involves an increase in expression of the cyclin-dependent kinase (CDK) inhibitor, p21(Cip1/Waf1) (where Cip1 is CDK-interacting protein 1 and Waf1 is wild-type p53-associated fragment 1), in response to M(3) AChR activation. This increase in protein expression leads to an increase in p21(Cip1/Waf1) association with CDK2, a decrease in CDK2 activity and an accumulation of hypophosphorylated retinoblastoma protein. The increased p21(Cip1/Waf1) expression is due, at least in part, to an increase in p21(Cip1/Waf1) mRNA, and receptor-mediated changes in phosphorylation of c-Jun provide a mechanism to account for this p21(Cip1/Waf1) transcriptional regulation. Evaluation of the extracellular signal-regulated protein kinase and c-Jun N-terminal kinase activities has shown striking differences in the profiles of activation of these mitogen-activated protein kinases by the M(2) and M(3) AChRs, and their potential involvement in mediating growth arrest by the M(3) AChR is discussed.

Calcium signals associated with migration and fusion of pronuclei in sea urchin eggs

l INSERM U 470, Centre de Biochimie, UNSA, Part Valrose, 06108 Nice Cedex 2, France; a giologie Cellulaire et Reproduction, UPRESA 6026 CNRS, Universftd de Rennes I, Campus de Beaulieu, Avenue du g&era1 Leclerc, 35042 Rennes Cedex, France; # Department of Biochemistry, University of Leicester, Adrian Building, University Road, Leicester LE 7Rli, United Kingdom;

Calcium and cell cycle control

Department of Physiolo NewcastleUpon-Tyne NE2 4H , By The Medical School, Framlington place, United Kingdom