Phosphodiesterase in human colon carcinoma cell line CaCo-2 in culture

In a series of in vitro experiments we characterised the relationship between DNA distribution in the G1, S and G2/M phases of cell cycle and PDE and GST activity in CaCo-2 cells. The DNA distribution in CaCo-2 cells, was assessed by flow cytometry, with fluorescent dyes at different time points of culture. The exponential increase in cell number continued until day 10 when there was cell saturation. The effect of medium replacement on PDE activity was assayed in the first 10 h after medium replacement. The 6^th hour is the time at which PDE activity was found to be highest. We have assayed the PDE enzyme with cGMP and cAMP as substrates. Only cAMP was consumed from this enzyme. We found a very close correlation between the DNA distribution in the various phases of the cell cycle and the PDE activity. PDE activity was very high during the active replication phase, whereas GST activity was high after confluency.     

Acute reduction of an origin recognition complex (ORC) subunit in human cells reveals a requirement of ORC for Cdk2 activation

The origin recognition complex (ORC) is involved in formation of prereplicative complexes (pre-RCs) on replication origins in the G1 phase. At the G1/S transition, elevated cyclin E-CDK2 activity triggers 1DNA replication to enter S phase. The CDK cycle works as an engine that drives progression of cell cycle events by successive activation of different types of cyclin-CDK. However, how the CDK cycle is coordinated with replication initiation remains elusive. Here we report that acute depletion of ORC2 by RNA interference (RNAi) arrests cells with low cyclin E-CDK2 activity. This result suggests that loss of a replication initiation protein prevents progression of the CDK cycle in G1. p27 and p21 proteins accumulate following ORC2 RNAi and are required for the CDK2 inhibition. Restoration of CDK activity by co-depletion of p27 and p21 allows many ORC2-depleted cells to enter S phase and go on to mitosis. However, in some cells the release of the CDK2 block caused catastrophic events like apoptosis. Therefore, the CDK2 inhibition observed following ORC2 RNAi seems to protect cells from premature S phase entry and crisis in DNA replication. These results demonstrate an unexpected role of ORC2 in CDK2 activation, a linkage that could be important for maintaining genomic stability.     

Role of the second-largest subunit of DNA polymerase alpha in the interaction between the catalytic subunit and hyperphosphorylated retinoblastoma protein in late S phase

DNA polymerase alpha (pol-alpha) is a heterotetrameric enzyme (p180-p68-p58-p48 in mouse) that is essential for the initiation of chain elongation during DNA replication. The catalytic (p180) and p68 subunits of pol-alpha are phosphorylated by Cdk-cyclin complexes, with p68 being hyperphosphorylated by cyclin-dependent kinases in G(2) phase of the cell cycle. The activity of Cdk2-cyclin A increases during late S phase and peaks in G(2) phase. We have now examined the role of p68 in the interaction between the catalytic subunit of pol-alpha and hyperphosphorylated retinoblastoma protein (ppRb) and in the stimulation of the polymerase activity of pol-alpha by ppRb. With the use of recombinant proteins, we found that nonphosphorylated p68 inhibited the stimulation of pol-alpha activity by ppRb, suggesting that p68 might impede the association of ppRb with p180. Phosphorylation of p68 by Cdk2-cyclin A greatly reduced its inhibitory effect. Immunofluorescence analysis also revealed that ppRb localized at sites of DNA replication specifically in late S phase. These results suggest that Cdk-cyclin A can phosphorylate pol-alpha which may result in a conformational change in pol-alpha facilitating its interaction with and activation by ppRb.     

The Stress-activated Protein Kinase Hog1 Mediates S Phase Delay in Response to Osmostress

Control of cell cycle progression by stress-activated protein kinases (SAPKs) is essential for cell adaptation to extracellular stimuli. Exposure of yeast to osmostress activates the Hog1 SAPK, which modulates cell cycle progression at G1 and G2 by the phosphorylation of elements of the cell cycle machinery, such as Sic1 and Hsl1, and by down-regulation of G1 and G2 cyclins. Here, we show that upon stress, Hog1 also modulates S phase progression. The control of S phase is independent of the S phase DNA damage checkpoint and of the previously characterized Hog1 cell cycle targets Sic1 and Hsl1. Hog1 uses at least two distinct mechanisms in its control over S phase progression. At early S phase, the SAPK prevents firing of replication origins by delaying the accumulation of the S phase cyclins Clb5 and Clb6. In addition, Hog1 prevents S phase progression when activated later in S phase or cells containing a genetic bypass for cyclin-dependent kinase activity. Hog1 interacts with components of the replication complex and delays phosphorylation of the Dpb2 subunit of the DNA polymerase. The two mechanisms of Hog1 action lead to delayed firing of origins and prolonged replication, respectively. The Hog1-dependent delay of replication could be important to allow Hog1 to induce gene expression before replication.     

tsLA23-NRK cells need pp60v-src protein-tyrosine kinase activity in G2 phase to initiate mitosis in serum-free medium.

Lowering the temperature from 41 to 36 degrees C stimulates quiescent tsLA23-NRK rat cells (infected with the tsLA23 mutant of the Rous sarcoma virus) in serum-free medium to resume cycling and initiate DNA replication by reactivating the tsLA23-RSV's abnormally thermolabile pp60v-src protein-tyrosine kinase. Inactivating the enzyme in these pp60v-src-stimulated cells by again raising the temperature to 41 degrees C after the cells had initiated DNA replication did not prevent the completion of DNA replication and entry into the G2 phase, but it stopped the initiation of mitosis. Adding serum at the time of the temperature increase replaced the lost pp60v-src activity and the cells were able to continue to mitosis. The G2-arrested cells at 41 degrees C were able to initiate mitosis when pp60v-src was reactivated again by lowering the temperature to 36 degrees C. These observations suggest that protein-tyrosine kinase activity is needed to initiate mitosis and that the tsLA23-NRK cell is a good model for studying the function of this kinase activity in the initiation of mitosis.     

Involvement of nuclear phosphatidylinositol-dependent phospholipases C in cell cycle progression during rat liver regeneration

Nuclear lipid metabolism is involved in the regulation of cell proliferation. Modulation of the expression and activity of nuclear PI-phospholipase C (PI-PLC) has been reported during liver regeneration after partial hepatectomy, although it has not been determined whether different PLC isoforms play specific roles in the regulation of cell cycle progression. Here, we report evidence that the increased activity of nuclear PLCs in regenerating rat liver occurs before the peak of DNA replication and involves the enzyme activity associated to the chromatin and not that associated to the nuclear membrane. Immunocytochemical analyses indicate that PI-PLC beta(1) isoform is exclusively localized at the chromatin level, PI-PLC beta(1) co-localizes with DNA replication sites much more than PI-PLC gamma(1), which is also present at the nuclear envelope. These findings and the increased amount of PI-PLC gamma(1) occurring after the peak of DNA replication suggest that PI-PLC beta(1) and gamma(1) play different roles in cell cycle progression during regenerating liver. The increased activity of PI-PLC beta(1) constitutively present within the hepatocyte nucleus, should trigger DNA replication, whereas PI-PLC gamma(1) should be involved in G2/M phase transition through lamin phosphorylation.     

Calmodulin-specific monoclonal antibodies inhibit DNA replication in mammalian cells.

The involvement of calmodulin in the proliferation of Chinese hamster embryo fibroblast cells has been studied with a specific monoclonal antibody to calmodulin. We observed that calmodulin levels increase 2-fold in the late G1 period in these cells, and this coincides with the increase in DNA polymerase alpha activity as the cells progress synchronously from a quiescent state in the G1 to the S phase. However, there is a concurrent 10-fold enhancement of thymidine kinase activity, which is tightly coupled to the entry of cells into the S phase. Incubation of permeabilized S-phase cells with calmodulin-specific murine monoclonal antibody resulted in a dose-dependent inhibition of DNA replication. This inhibitory effect of anti-calmodulin antibodies on DNA replication is completely reversed by the addition of exogenously purified calmodulin. These observations provide evidence for the involvement of calmodulin in DNA replication and, therefore, in cell proliferation during the S phase.     

The replication factory targeting sequence/PCNA-binding site is required in G(1) to control the phosphorylation status of DNA ligase I.

The recruitment of DNA ligase I to replication foci in S phase depends on a replication factory targeting sequence that also mediates the interaction with proliferating cell nuclear antigen (PCNA) in vitro. By exploiting a monoclonal antibody directed at a phospho-epitope, we demonstrate that Ser66 of DNA ligase I, which is part of a strong CKII consensus site, is phosphorylated in a cell cycle-dependent manner. After dephosphorylation in early G(1), the level of Ser66 phosphorylation is minimal in G(1), increases progressively in S and peaks in G(2)/M phase. The analysis of epitope-tagged DNA ligase I mutants demonstrates that dephosphorylation of Ser66 requires both the nuclear localization and the PCNA-binding site of the enzyme. Finally, we show that DNA ligase I and PCNA interact in vivo in G(1) and S phase but not in G(2)/M. We propose that dephosphorylation of Ser66 is part of a novel control mechanism to establish the pre-replicative form of DNA ligase I.     

Cell Cycle Control of Cdc7p Kinase Activity through Regulation of Dbf4p Stability

In Saccharomyces cerevisiae, the heteromeric kinase complex Cdc7p-Dbf4p plays a pivotal role at replication origins in triggering the initiation of DNA replication during the S phase. We have assayed the kinase activity of endogenous levels of Cdc7p kinase by using a likely physiological target, Mcm2p, as a substrate. Using this assay, we have confirmed that Cdc7p kinase activity fluctuates during the cell cycle; it is low in the G1 phase, rises as cells enter the S phase, and remains high until cells complete mitosis. These changes in kinase activity cannot be accounted for by changes in the levels of the catalytic subunit Cdc7p, as these levels are constant during the cell cycle. However, the fluctuations in kinase activity do correlate with levels of the regulatory subunit Dbf4p. The regulation of Dbf4p levels can be attributed in part to increased degradation of the protein in G1 cells. This G1-phase instability is cdc16 dependent, suggesting a role of the anaphase-promoting complex in the turnover of Dbf4p. Overexpression of Dbf4p in the G1 phase can partially overcome this elevated turnover and lead to an increase in Cdc7p kinase activity. Thus, the regulation of Dbf4p levels through the control of Dbf4p degradation has an important role in the regulation of Cdc7p kinase activity during the cell cycle.     

Mutagenesis of D80-82 and G83 residues in West Nile Virus NS2B: Effects on NS2B-NS3 activity and viral replication

Flaviviral NS2B is a required cofactor for NS3 serine protease activity and plays an important role in promoting functional NS2B-NS3 protease configuration and maintaining critical interactions with protease catalysis substrates. The residues D⁸⁰DDG in West Nile virus (WNV) NS2B are important for protease activity. To investigate the effects of D⁸⁰DDG in NS2B on protease activity and viral replication, the negatively charged region D⁸⁰DD and the conserved residue G83 of NS2B were mutated (D⁸⁰DD/E⁸⁰EE, D⁸⁰DD/K⁸⁰KK, D⁸⁰DD/A⁸⁰AA, G83F, G83S, G83D, G83K, and G83A), and NS3 D75A was designated as the negative control. The effects of the mutations on NS2B-NS3 activity, viral translation, and viral RNA replication were analyzed using kinetic analysis of site-directed enzymes and a transient replicon assay. All substitutions resulted in significantly decreased enzyme activity and blocked RNA replication. The negative charge of D⁸⁰DD is not important for maintaining NS2B function, but side chain changes in G83 have dramatic effects on protease activity and RNA replication. These results demonstrate that NS2B is important for viral replication and that D⁸⁰DD and G83 substitutions prevent replication; they will be useful for understanding the relationship between NS2B and NS3.     

Human CDK2 Inhibition Modifies the Dynamics of Chromatin-Bound Minichromosome Maintenance Complex and Replication Protein A

Minichromosome maintenance (MCM) proteins form a complex and possess helicase activity to unwind the DNA duplex and establish a replication fork. To assure that origins only fire once per cell cycle, the MCM complex is removed from chromatin and inactivated as cells exit S phase. In this report, we demonstrate that CDK2 depletion in human cells leads to an overall phosphorylation defect at mitosis with increased rereplication, correlated with the accumulation of chromatin-bound MCM proteins. We show that CDK2 suppression results in decreased MCM4 phosphorylation at multiple serine and threonine sites. In addition, CDK2 inhibition induces an increase in chromatin-bound replication protein A (RPA) which should bindto single-stranded DNA regions, possibly establishing a replication intermediate that activates the ATR cascade. Finally, we observe that loss of CDK2 function in G1 delays replication initiation while it promotes rereplication in G2/M. Thus, by modulating the phospho-status of MCM4 and regulating origin firing, S phase CDK2 appears to be an integrated component of cellular machinery required for temporally controlling replication activity and maintaining genomic stability.     

Uncoupling global and fine-tuning replication timing determinants for mouse pericentric heterochromatin

Mouse chromocenters are clusters of late-replicating pericentric heterochromatin containing HP1 bound to trimethylated lysine 9 of histone H3 (Me3K9H3). Using a cell-free system to initiate replication within G1-phase nuclei, we demonstrate that chromocenters acquire the property of late replication coincident with their reorganization after mitosis and the establishment of a global replication timing program. HP1 dissociated during mitosis but rebound before the establishment of late replication, and removing HP1 from chromocenters by competition with Me3K9H3 peptides did not result in early replication, demonstrating that this interaction is neither necessary nor sufficient for late replication. However, in cells lacking the Suv39h1,2 methyltransferases responsible for K9H3 trimethylation and HP1 binding at chromocenters, replication of chromocenter DNA was advanced by 10-15% of the length of S phase. Reintroduction of Suv39h1 activity restored the later replication time. We conclude that Suv39 activity is required for the fine-tuning of pericentric heterochromatin replication relative to other late-replicating domains, whereas separate factors establish a global replication timing program during early G1 phase.     

Stress-stimulated mitogen-activated protein kinases control the stability and activity of the Cdt1 DNA replication licensing factor

DNA replication is tightly coordinated both with cell cycle cues and with responses to extracellular signals to maintain genome stability. We discovered that human Cdt1, an essential origin licensing protein whose activity must be restricted to G(1) phase, is a substrate of the stress-activated mitogen-activated protein (MAP) kinases p38 and c-Jun N-terminal kinase (JNK). These MAP kinases phosphorylate Cdt1 both during unperturbed G(2) phase and during an acute stress response. Phosphorylation renders Cdt1 resistant to ubiquitin-mediated degradation during S phase and after DNA damage by blocking Cdt1 binding to the Cul4 adaptor, Cdt2. Mutations that block normal cell cycle-regulated MAP kinase-mediated phosphorylation interfere with rapid Cdt1 reaccumulation at the end of S phase. Phosphomimetic mutations recapitulate the stabilizing effects of Cdt1 phosphorylation but also reduce the ability of Cdt1 to support origin licensing. Two other CRL4(Cdt2) targets, the cyclin-dependent kinase (CDK) inhibitor p21 and the methyltransferase PR-Set7/Set8, are similarly stabilized by MAP kinase activity. These findings support a model in which MAP kinase activity in G(2) promotes reaccumulation of a low-activity Cdt1 isoform after replication is complete.