Changes in the nuclear distribution of cyclin (PCNA) but not its synthesis depend on DNA replication.

Synthesis of cyclin in serum-stimulated quiescent 3T3 cells increases shortly before DNA synthesis after 10 h of stimulation, reaching a maximum after 16 h. Inhibition of DNA synthesis by hydroxyurea does not affect the increase of cyclin following stimulation, as determined by quantitative two-dimensional gel electrophoresis. The levels of cyclin decrease dramatically at the end of the S-phase. Cells kept in the presence of hydroxyurea (G1/S boundary) do not show this decrease in cyclin, indicating that its amounts are regulated by events occurring during the S-phase. Immunofluorescence studies of serum-stimulated quiescent cells in the presence of hydroxyurea, using proliferating cell nuclear antigen (PCNA) autoantibodies, confirm the results obtained by protein analysis. They also reveal that there are dramatic changes in the nuclear distribution of cyclin and that these depend on DNA synthesis or events occurring during the S-phase. Cyclin (PCNA) is no longer detectable at the end of the S-phase. However, pulse-chase experiments indicate that this protein is very stable, suggesting that it possibly interacts with other macromolecules rendering it inaccessible to the antibody. These results strengthen the notion that cyclin is an important component of the events leading to DNA replication and cell division.     

Induction of the nuclear protein cyclin in serum-stimulated quiescent 3T3 cells is independent of DNA synthesis

Inhibition of DNA synthesis and cell proliferation of mouse 3T3 cells by aphidicolin did not affect the expression of cyclin, a nuclear protein whose synthesis correlates with cell proliferation, as determined by quantitative two-dimensional gel electrophoresis analysis. Serum stimulation of quiescent 3T3 cells revealed that cyclin synthesis increases shortly before DNA synthesis. Inhibition of DNA synthesis by aphidicolin in serum-stimulated quiescent cells did not affect the increase of cyclin following stimulation. These results demonstrate that cyclin synthesis is not coupled to DNA synthesis and that it is one of the latest events before DNA replication.     

Existence of two populations of cyclin/proliferating cell nuclear antigen during the cell cycle: association with DNA replication sites

Pulse-chase experiments have revealed that cyclin, the auxiliary protein of DNA polymerase-delta, is stable during the transition from growth to quiescence in 3T3 cells. Immunoblotting together with immunofluorescence analysis has shown that the amount of cyclin after 24 h of quiescence is 30-40% of that of growing cells and that it presents a nucleoplasmic staining. Immunofluorescence studies show the existence of two populations of cyclin during the S phase, one that is nucleoplasmic as in quiescent cells and is easily extracted by detergent, and another that is associated to specific nuclear structures. By using antibromodeoxyuridine immunofluorescence to detect the sites of DNA synthesis, it was shown that the staining patterns of the replicon clusters and their order of appearance throughout the S phase are identical to those observed for cyclin. Two-dimensional gel analysis of Triton-extracted cells show that 20-30% of cyclin remains associated with the replicon clusters. This population of cyclin could not be released from the nucleus using high-salt extractions. This demonstrates that cyclin is tightly associated to the sites of DNA replication and that it must have a fundamental role in DNA synthesis in eukaryotic cells.     

Induction of the nuclear protein ''cyclin'' in quiescent mouse 3T3 cells stimulated by serum and growth factors. Correlation with DNA synthesis

The effect of serum and growth factors [platelet-derived growth factor (PDGF), fibroblast growth factor (FGF)] on the synthesis of the nuclear protein cyclin and its correlation with DNA synthesis has been studied in quiescent mouse 3T3 cells by means of quantitative two-dimensional gel electrophoresis. Serum must be present in the medium for at least 8-12 h to induce maximal synthesis of cyclin (6- to 7-fold increase compared with quiescent cells). The stimulation of cyclin synthesis is dose-dependent and correlates directly with DNA synthesis. In addition, partially purified PDGF and FGF also induce cyclin and DNA synthesis in a coordinate way. Both growth factors, like serum, exhibit a similar lag phase to induce maximal cyclin (6- to 7-fold) and DNA synthesis (90% of the cells). Pure PDGF at a concentration as low as 10 ng/ml has the same effect as 10% serum. The coordinate induction of cyclin and DNA synthesis can only be observed with growth factors that induce DNA synthesis. These results strengthen the notion that cyclin is an essential component of the events leading to DNA replication.     

Requirement for proliferating cell nuclear antigen expression during stages of the Chinese hamster ovary cell cycle

Proliferating cell nuclear antigen (PCNA/cyclin) is a nuclear protein that can stimulate purified DNA polymerase delta in vitro, and its synthesis correlates with the proliferation rate of cells. We have attempted to determine whether synthesis of PCNA/cyclin in Chinese hamster ovary cells is necessary to regulate entry into S phase. We have measured cellular PCNA/cyclin concentration of the mRNA or protein throughout the cell cycle. Cells were separated by centrifugal elutriation into populations enriched for G-1, S, and G-2/M phases. Quantitative Northern hybridization analysis was performed on RNA isolated from each cell population by using a cDNA clone of PCNA/cyclin as a probe. Results demonstrated that although intact PCNA/cyclin mRNA is present during all phases of the cell cycle, an induction of about 3-fold occurs during S phase. Two-parameter staining for PCNA/cyclin and DNA, and analysis by flow cytometry, confirmed that the quantity of PCNA/cyclin protein in the cells increases severalfold in G-1 or early S phase but generally is invariant in S and G-2/M phases. This cell cycle dependence of PCNA/cyclin expression suggests that the observed synthesis is a prerequisite for initiation of DNA replication. Introduction of an antisense oligonucleotide complementary to the PCNA/cyclin mRNA to inhibit PCNA/cyclin synthesis effectively prevented entry of G-1 phase cells into S phase. A complementary sense oligonucleotide used as a control did not have an inhibitory effect. This result suggests that a threshold concentration of PCNA/cyclin is necessary for entry into S phase.     

Cyclin D1 serves as a cell cycle regulatory switch in actively proliferating cells

Much of our current understanding of the cell cycle involves analyses of its induction in quiescent cells. To better understand the control of cell cycle propagation and termination, studies have been performed in actively cycling cultures using time-lapse photography and quantitative image analysis. These studies reveal a highly ordered sequence of events required for promotion of continued proliferation. The decision to continue cell cycle progression takes place in G2 phase, when cellular Ras induces the elevation of cyclin D1 levels. These levels are maintained through G1 phase and are required for the initiation of S phase, at which time cyclin D1 levels are automatically reduced to low levels. The reduction of cyclin D1 to low levels during S phase is required for DNA synthesis, and forces the cell to induce high cyclin D1 levels once again when it enters G2 phase. In this way, cyclin D1 is proposed to serve as an active switch in the regulation of continued cell cycle progression.     

Cyclin A is required for the onset of DNA replication in mammalian fibroblasts.

Cyclin A protein is synthesized and localized into the nucleus at the onset of S phase in nontransformed mammalian fibroblasts. Inhibition of cyclin A synthesis or activity through microinjection of plasmids encoding antisense cyclin A cDNA or affinity-purified anti-cyclin A antibodies during G1 phase was shown to abolish the nuclear staining for cyclin A in plasmid-injected cells, and both procedures led to inhibition of DNA synthesis. No similar effect was observed with injection of other antisense vectors including antisense cyclin B, and reinjection of purified human cyclin A protein into cyclin A antisense-injected cells effectively relieved this inhibition of DNA synthesis. Taken together, these data suggest that cyclin A plays a major role in the control of DNA replication in mammalian cells.     

Follicle stimulating hormone-induced DNA synthesis in the granulosa cells of hamster preantral follicles involves activation of cyclin-dependent kinase-4 rather than cyclin d2 synthesis

Although cyclin D2 mRNA synthesis precedes gonadotropin-induced DNA synthesis in quiescent granulosa cells in culture, it is unclear whether a similar mechanism exists for the granulosa cells of growing preantral follicles in cyclic animals. The objective was to evaluate whether the synthesis of cyclin D2 protein was a prerequisite for FSH-induced DNA synthesis in the granulosa cells of intact preantral follicles of cyclic hamsters. Preantral follicles from cyclic hamsters were cultured in the presence or absence of FSH, and cell cycle parameters were examined. FSH stimulated cyclin-dependent kinase (CDK)-4 activity by 2 h and DNA synthesis by 4 h without altering the levels of cyclin D2 in the granulosa cells. The FSH effect was mimicked by epidermal growth factor administered in vivo. Although FSH increased the levels of cyclin D2 mRNA, it also stimulated the degradation of cyclin D2 as well as p27(Kip1) and p19(INK4) proteins. FSH activation of CDK4 was mediated by cAMP and ERK-1/2. In contrast to granulosa cells in intact follicles, FSH or cAMP significantly increased cyclin D2 protein levels in cultured granulosa cells but failed to induce DNA synthesis. Collectively, these data suggest that granulosa cells of preantral follicles, which are destined to enter the S phase during the estrous cycle, contain necessary amounts of cyclin D2 and other G1 phase components. FSH stimulation results in the formation and activation of the cyclin D2/CDK4 complex leading to DNA synthesis. This mechanism may be necessary for rapid movement of follicles from preantral to antral stages during the short duration of the murine estrous cycle.     

Cyclin A-CDK activity during G1 phase impairs MCM chromatin loading and inhibits DNA synthesis in mammalian cells

Progression through the mammalian cell division cycle is regulated by the sequential activation of cyclin-dependent kinases, CDKs, at specific phases of the cell cycle. Cyclin A-CDK2 and cyclin A-CDK1 phosphorylate nuclear substrates during S and G2 phases, respectfully. However, the DNA helicase complex, MCM2-7, is loaded onto the origin of replications in G1, prior to the normally scheduled induction of cyclin A. It has previously been shown that cyclin A-CDKs phosphorylate MCM2 and MCM4 in vitro, thereby diminishing helicase activity. Thus, in this study we hypothesize that, in vivo, cyclin A-CDK activity during G1 would result in an inhibition of progression into the S phase. To test this, we establish an in vivo method of inducing cyclin A-CDK activity in G1 phase and observe that activation of cyclin A-CDK, but not cyclin E-CDK complexes, inhibit DNA synthesis without affecting other G1 events such as cyclin D synthesis, E2F activation and cdc6 loading onto chromatin. We further report that the mechanism of this S phase inhibition occurs, at least in part, through impaired loading of MCM onto chromatin, presumably due to decreased levels of cdt1 and premature phosphorylation of MCM by cyclin A-CDK. In addition to providing in vivo confirmation of in vitro predictions regarding cyclin A-CDK phosphorylation of the MCM complex, our results provide insight into the cellular effects of unscheduled cyclin A-CDK activity in mammalian cells.     

Expression and subcellular localization of CDK2 and cdc2 kinases and their common partner cyclin A in thyroid epithelial cells: Comparison of cyclic AMP-dependent and -independent cell cycles

Dog thyroid epithelial cells in primary culture constitute a model of positive control of DNA synthesis initiation and GO-S prereplicative phase progression by cyclic AMP as a second messenger for TSH. In its early steps, this mitogenic control is quite distinct from cyclic AMP-independent mitogenic cascades elicited by growth factors. We demonstrate here that TSH (cyclic AMP) and EGF + serum (cyclic AMP-independent) stimulations cooperate and finally converge on proteins that control the cell cycle machinery. This convergence included a common induction of the expression of cyclin A and p34^cdc2, and to a lesser extent of p33/38^cdk2, which was already expressed in quiescent thyroid cells, and common changes of cdc2 and CDK2 phosphorylations as evidenced by electrophoretic mobility shifts. Kinetic differences in these processes after stimulation by TSH or EGF + serum or by these factors in combination correlated with differences in cell cycle kinetics. Moreover, an immunofluorescence analysis of these proteins using the double labeling of PCNA as a marker of each cell cycle phase shows: (1) a previously undescribed nuclear translocation of CDK2 before S phase initiation; (2) a sudden increase of cdc2 nuclear immunoreactivity at G2/mitosis transition. These data support the roles of CDK2 and cdc2 at G1/S and G2/mitosis transitions, respectively. (3) We were unable to demonstrate in individual cells a strict association between the nuclear appearance of cyclin A and G1/S transition, and an association of cyclin A and CDK2 with PCNA-stained DNA replication sites. On the other hand, the lengthening of G2 phase in the TSH/cyclic AMP-dependent thyroid cell cycle was associated with a stabilization of Tyr15 inhibitory phosphorylation of cdc2 and an especially high nuclear concentration of cyclin A and CDK2. We hypothesize that high nuclear accumulation of cyclin A and CDK2 during G2 phase could be causative in the cyclic AMP-dependent delay of mitosis onset. © 1996 Wiley-Liss, Inc.     

Cellular Ras and Cyclin D1 Are Required during Different Cell Cycle Periods in Cycling NIH 3T3 Cells

Novel techniques were used to determine when in the cell cycle of proliferating NIH 3T3 cells cellular Ras and cyclin D1 are required. For comparison, in quiescent cells, all four of the inhibitors of cell cycle progression tested (anti-Ras, anti-cyclin D1, serum removal, and cycloheximide) became ineffective at essentially the same point in G1 phase, approximately 4 h prior to the beginning of DNA synthesis. To extend these studies to cycling cells, a time-lapse approach was used to determine the approximate cell cycle position of individual cells in an asynchronous culture at the time of inhibitor treatment and then to determine the effects of the inhibitor upon recipient cells. With this approach, anti-Ras antibody efficiently inhibited entry into S phase only when introduced into cells prior to the preceding mitosis, several hours before the beginning of S phase. Anti-cyclin D1, on the other hand, was an efficient inhibitor when introduced up until just before the initiation of DNA synthesis. Cycloheximide treatment, like anti-cyclin D1 microinjection, was inhibitory throughout G1 phase (which lasts a total of 4 to 5 h in these cells). Finally, serum removal blocked entry into S phase only during the first hour following mitosis. Kinetic analysis and a novel dual-labeling technique were used to confirm the differences in cell cycle requirements for Ras, cyclin D1, and cycloheximide. These studies demonstrate a fundamental difference in mitogenic signal transduction between quiescent and cycling NIH 3T3 cells and reveal a sequence of signaling events required for cell cycle progression in proliferating NIH 3T3 cells.     

Ultrastructural immunolocalization of cyclin/PCNA in synchronized 3T3 cells

The immunolocalization of cyclin/PCNA in synchronized 3T3 cells was performed with human autoantibodies using an immunogold technique performed on thin cryosections. Previous immunofluorescent studies demonstrated that the DNA replication sites correspond to the localization of bound cyclin. We have found that in the early periods of S phase, the DNA replication sites (or sites potentially ready for the replication during the hydroxyurea DNA synthesis block) are situated in the perichromatin region and correspond to clustered gold particles present frequently over a morphologically distinct small nuclear area. Heavily labeled chromocenters, including perinucleolar condensed chromatin, exhibiting several such distinct areas were found in later periods of S phase.     

Coordinated regulation of M phase exit and S phase entry by the Cdc2 activity level in the early embryonic cell cycle

In the early embryonic cell cycle, exit from M phase is immediately followed by entry into S phase without an intervening gap phase. To understand the regulatory mechanisms for the cell cycle transition from M to S phase, we examined dependence on Cdc2 inactivation of cell-cycle events occurring during the M-S transition period, using Xenopus egg extracts in which the extent of Cdc2 inactivation at M phase exit was quantitatively controlled. The result demonstrated that MCM binding to and the initiation of DNA replication of nuclear chromatin occurred depending on the decrease of Cdc2 activity to critical levels. Similarly, we found that Cdc2 inhibitory phosphorylation and cyclin B degradation were turned on and off, respectively, depending on the decrease in Cdc2 activity. However, their sensitivity to Cdc2 activity was different, with the turning-on of Cdc2 inhibitory phosphorylation occurring at higher Cdc2 activity levels than the turning-off of cyclin B degradation. This means that, when cyclin B degradation ceases at M phase exit, Cdc2 inhibitory phosphorylation is necessarily activated. In the presence of constitutive synthesis of cyclin B, this condition favors the occurrence of the Cdc2 inactivation period after M phase exit, thereby ensuring progression through S phase. Thus, M phase exit and S phase entry are coordinately regulated by the Cdc2 activity level in the early embryonic cell cycle.     

Human cytomegalovirus infection inhibits G1/S transition.

Cell cycle progression during cytomegalovirus infection was investigated by fluorescence-activated cell sorter (FACS) analysis of the DNA content in growth-arrested as well as serum-stimulated human fibroblasts. Virus-infected cells maintained in either low (0.2%) or high (10%) serum failed to progress into S phase and failed to divide. DNA content analysis in the presence of G1/S (hydroxyurea and mimosine) and G2/M (nocodazole and colcemid) inhibitors demonstrated that upon virus infection of quiescent (G0) cells, the cell cycle did not progress beyond the G1/S border even after serum stimulation. Proteins which normally indicate G1/S transition (proliferating cell nuclear antigen [PCNA]) or G2/M transition (cyclin B1) were elevated by virus infection. PCNA levels were induced in infected cells and exhibited a punctate pattern of nuclear staining instead of the diffuse pattern observed in mock-infected cells. Cyclin B1 was induced in infected cells which exhibited a G1/S DNA content by FACS analysis, suggesting that expression of this key cell cycle function was dramatically altered by viral functions. These data demonstrate that contrary to expectations, cytomegalovirus inhibits normal cell cycle progression. The host cell is blocked prior to S phase to provide a favorable environment for viral replication.     

Binding of Polyomavirus Small T Antigen to Protein Phosphatase 2A Is Required for Elimination of p27 and Support of S-Phase Induction in Concert with Large T Antigen

Although polyomavirus large T antigen readily transactivates S-phase-specific enzymes in serum-starved Swiss 3T3 mouse fibroblasts, it is incapable by itself to efficiently drive such cells into S phase. We describe here that this inability correlates with a weak proficiency of the viral protein to induce the synthesis of cyclin A and cyclin E and to stimulate the respective cyclin/cdk activities. Polyomavirus small T antigen, which together with the large T protein supports S-phase induction, strongly contributes to the synthesis of cyclin A. In addition, small T antigen causes a dramatic induction of cyclin A- and, together with large T antigen, of cyclin E-specific protein kinase activity. This latter function of polyomavirus small T antigen correlates with its competence to provoke the elimination of the kinase inhibitor p27(Kip1). An interaction of the small T antigen with the protein phosphatase 2A is essential for this activity. Hence, the ability to drive quiescent Swiss 3T3 cells into S phase results from the capacity of large T antigen to transactivate DNA synthesis enzymes by its interaction with retinoblastoma-type proteins and from the potential of the large and the small T antigens together to stimulate cyclin A synthesis and cyclin A- and cyclin E-dependent protein kinase activity.     

Changes in cyclin/proliferating cell nuclear antigen distribution during DNA repair synthesis

UV irradiation of quiescent human fibroblasts immediately triggers the appearance of the nuclear protein cyclin/proliferating cell nuclear antigen (PCNA) as detected by indirect immunofluorescent staining after methanol fixation. This was found to be independent of new synthesis of cyclin/PCNA by two-dimensional gel analysis and cycloheximide treatment. The intensity of the immunofluorescent staining of cyclin/PCNA observed in UV-irradiated cells corresponded with the UV dose used and with the DNA repair synthesis detected by autoradiography. The nuclear staining remains as long as DNA repair activity is detected in the cells. By extracting the UV-irradiated quiescent cells with Triton X-100 and fixing with formaldehyde, it was possible to demonstrate by indirect immunofluorescence rapid changes in the cyclin/PCNA population after irradiation, a small proportion (5-10%) of which is tightly associated to the nucleus as determined by high salt extraction. By incubating at low temperature and depleting the ATP pools of the cells before UV irradiation, we have demonstrated that the changes in cyclin/PCNA distribution observed involve at least two different nuclear associations.     

Inhibition of nuclear DNA synthesis by an autoantibody to proliferating cell nuclear antigen/cyclin

Proliferating cell nuclear antigen (PCNA) is expressed in the nuclei of proliferating cells, but is not detected in resting cells. The kinetics of PCNA expression suggest that it is associated with a phase preceding active DNA synthesis. DNA synthesis is under cytoplasmic control, and there is a cytoplasmic protein, ADR (activator of DNA replication), that induces DNA synthesis in isolated quiescent nuclei. We now report that a human antibody preparation monospecific for PCNA, but not two monoclonal antibodies directed against different epitopes on PCNA, can inhibit the ability of ADR to induce DNA synthesis in isolated quiescent nuclei. This effect is not due to inhibition of DNA polymerase alpha activity. Thus, the anti-PCNA antibody exerts its effect either by directly influencing the initial interaction of ADR with the nucleus, or by inhibiting subsequent synthetic events.     

The spatial organization of sequences involved in initiation and termination of eukaryotic DNA replication.

Nuclear DNA is looped by attachment to a matrix or cage. As this cage is the site of DNA synthesis, sequences in the loops must attach before they are replicated. We have tested whether sequences which initiate replication are usually out in the loop and attach only during S phase or whether they are attached but quiescent during most of the cell-cycle. Sequences which permit plasmids to replicate autonomously in yeast cells (ARS's) are strong candidates for initiating sequences. Four different human ARS's all map remote from attachment points to the HeLa nuclear cage. In addition a potential terminus of replication is also remote from the cage. We conclude that sequences involved in initiation are usually out in the loop and that DNA synthesis is initiated by their attachment.