A new compound which reversibly arrests T lymphocyte cell cycle near the G1/S boundary

A novel cell cycle blocking agent profoundly suppressed the proliferation of mitogen-stimulated T lymphocytes. The carboxythiazole derivative arrested cells in the G1 phase of the cell cycle but did not inhibit the induction of cell surface receptors for either interleukin-2 or transferrin. The uncoupling of transferrin receptor expression from DNA synthesis indicated that a previously undefined restriction point in the cell cycle has been identified which occurs after transferrin receptor expression in late G1 and just prior to the initiation of DNA replication in S phase. T cells incubated in an inhibitory dose of the carboxythiazole derivative resumed cell cycle progression subsequent to its removal, indicating that the compound reversibly arrests cells at the late G1 restriction point. In contrast to other techniques which have been inefficient in achieving T cell synchronization, T cells released from the block mediated by the carboxythiazole compound progress through S phase with a considerable degree of synchrony.     

Mimosine reversibly arrests cell cycle progression at the G1-S phase border

It has previously been demonstrated that the compound mimosine inhibits cell cycle traverse in late G1 phase prior to the onset of DNA synthesis (Hoffman BD, Hanauske-Abel HM, Flint A, Lalande M: Cytometry 12:26-32, 1991; Lalande M: Exp Cell Res 186:332-339, 1990). These results were obtained by using flow cytometric analysis of DNA content to compare the effects of mimosine on cell cycle traverse with those of aphidicolin, an inhibitor of DNA polymerase alpha activity. We have now measured the incorporation of bromodeoxyuridine into lymphoblastoid cells by flow cytometry to determine precisely where the two inhibitors act relative to the initiation of DNA synthesis. It is demonstrated here that mimosine arrests cell cycle progression at the G1-S phase border. The onset of DNA replication occurs within 15 min of releasing the cells from the mimosine block. In contrast, treatment with aphidicolin results in the accumulation of cells in early S phase. These results indicate that mimosine is a suitable compound for affecting the synchronous release of cells from G1 into S phase and for analyzing the biochemical events associated with this cell cycle phase transition.     

Transfer RNA(4lys) and cell cycle progression: characterization of ts-694 cells

Lysine tRNA modification has been studied in mammalian ts-694 cells with respect to cell cycle progression in temperature downshift and upshift experiments. The modification of tRNA(lys) measured in temperature downshift experiments showed that tRNA(4lys) levels start to increase 6 h following the temperature shift, approximately 10-12 h prior to the cells entry into S phase. Ts-694 cells showed a gradual decrease in the level of tRNA(4lys) and the rates of DNA synthesis following a temperature upshift. The cells became growth arrested following incubation for 36-45 h at the rt. Cell cycle mapping of the temperature restriction point suggests a G1 block prior to the serum deprivation restriction point. Depletion of cellular tRNA(4lys) by serum deprivation followed by simultaneously shifting cells to the rt and feeding medium containing 10% serum showed that cells with low tRNA(4lys) levels and no mechanism for the synthesis of tRNA(4lys) could not enter S phase and synthesize DNA. Blocking of ts-694 at the G1/S boundary with aphidicolin indicates that cells that have passed through G1 are capable of entering S phase and synthesizing DNA independent of the incubation temperature. These results indicate that tRNA(4lys) is not needed during S phase for DNA replication but suggests that tRNA(4lys) is required for cells to progress through G1.     

Regulation of dog thyroid epithelial cell cycle by forskolin, an adenylate cyclase activator

Dog thyroid epithelial follicular cells in primary culture are quiescent in an insulin-supplemented serum-free medium. They are induced, after a 16- to 20-h prereplicative phase, to synthesize DNA upon stimulation by forskolin, a general adenylate cyclase activator that mimics all the effects of thyrotropin in these cells. The characteristics of adenylate cyclase activation by forskolin make this drug a convenient tool to enhance cellular cyclic AMP levels for well-defined periods of the cell cycle, allowing determination of which parts of the prereplicative phase are controlled by cyclic AMP. We observe that induction of DNA synthesis by forskolin requires its continuous presence for most of the prereplicative phase until a point that little precedes the initiation of DNA replication. Before this point, interruptions in forskolin presence as short as 2 h delay the onset of DNA synthesis, indicating a rapid regression of the cells to an earlier part of G1 from which they can be rescued by forskolin readdition. Similar delays in the onset of S phase are also induced by reversible protein synthesis inhibitions using pulses of cycloheximide. These data suggest that in dog thyrocytes elevated cyclic AMP levels stimulate the progression into G1 phase until a late commitment point before DNA synthesis. This progression depends on peculiarly labile cyclic AMP-stimulated events which might well be the induction by cyclic AMP of the synthesis of labile proteins.     

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.     

Centriole ciliation and cell cycle variability during G1 phase of BALB/c 3T3 cells

Although variability in the duration of the cell cycle is thought to reflect growth-regulatory processes that control cell cycle progression, the precise timing of the variable period within the G1 phase of the cell cycle has not been defined. In particular, the timing of cell cycle variability in relation to the cell's commitment (R point) to the initiation of DNA synthesis remains controversial. In order to investigate cell cycle variability, indirect immunofluorescence was used to measure the formation of the primary cilium as a possible marker of G1 events in both stimulated quiescent and exponentially growing cells. The primary cilium, an internal "9 + 0" nonmotile structure formed by one of the interphase centrioles, was first detected in postmitotic BALB/c 3T3 cells 5 hr before the initiation of DNA synthesis, an interval similar to that for the reassembly of the primary cilium in serum-stimulated quiescent fibroblasts. This similarity in the timing of ciliation suggests that serum-stimulated quiescent cells reenter the cell cycle in early G1 and recapitulate much of G1. Moreover, the rate of cilia formation in both postmitotic and serum-stimulated quiescent cells was identical to the rate of DNA synthesis initiation. Thus, cell cycle variability occurs before ciliation in both stimulated quiescent and exponentially growing cells. Furthermore, since ciliation also precedes the R point, variability in the centriole cycle occurs before the R point and thus may reflect processes controlling the cell's commitment to the initiation of DNA synthesis.     

Dependence of DNA synthesis and in vitro development of bovine nuclear transfer embryos on the stage of the cell cycle of donor cells and recipient cytoplasts

The effect of the stage of the cell cycle of donor cells and recipient cytoplasts on the timing of DNA replication and the developmental ability in vitro of bovine nuclear transfer embryos was examined. Embryos were reconstructed by fusing somatic cells with unactivated recipient cytoplasts or with recipient cytoplasts that were activated 2 h before fusion. Regardless of whether recipient cytoplasts were unactivated or activated, the embryos that were reconstructed from donor cells at the G0 phase initiated DNA synthesis at 6-9 h postfusion (hpf). The timing of DNA synthesis was similar to that of parthenogenetic embryos, and was earlier than that of the G0 cells in cell culture condition. Most embryos that were reconstructed from donor cells at the G1/S phase initiated DNA synthesis within 6 hpf. The developmental rate of embryos reconstructed by a combination of G1/S cells and activated cytoplasts was higher than the rates of embryos in the other combination of donor cells and recipient cytoplasts. The results suggest that the initial DNA synthesis of nuclear transfer embryos is affected by the state of the recipient oocytes, and that the timing of initiation of the DNA synthesis depends on the donor cell cycle. Our results also suggest that the cell cycles of somatic cells synchronized in the G1/S phase and activated cytoplasts of recipient oocytes are well coordinated after nuclear transfer, resulting in high developmental rates of nuclear transfer embryos to the blastocyst stage in vitro.     

Identification of an arginine-rich motif in human papillomavirus type 1 E1;E4 protein necessary for E4-mediated inhibition of cellular DNA synthesis in vitro and in cells

Productive infections by human papillomaviruses (HPVs) are restricted to nondividing, differentiated keratinocytes. HPV early proteins E6 and E7 deregulate cell cycle progression and activate the host cell DNA replication machinery in these cells, changes essential for virus synthesis. Productive virus replication is accompanied by abundant expression of the HPV E4 protein. Expression of HPV1 E4 in cells is known to activate cell cycle checkpoints, inhibiting G(2)-to-M transition of the cell cycle and also suppressing entry of cells into S phase. We report here that the HPV1 E4 protein, in the presence of a soluble form of the replication-licensing factor (RLF) Cdc6, inhibits initiation of cellular DNA replication in a mammalian cell-free DNA replication system. Chromatin-binding studies show that E4 blocks replication initiation in vitro by preventing loading of the RLFs Mcm2 and Mcm7 onto chromatin. HPV1 E4-mediated replication inhibition in vitro and suppression of entry of HPV1 E4-expressing cells into S phase are both abrogated upon alanine replacement of arginine 45 in the full-length E4 protein (E1;E4), implying that these two HPV1 E4 functions are linked. We hypothesize that HPV1 E4 inhibits competing host cell DNA synthesis in replication-activated suprabasal keratinocytes by suppressing licensing of cellular replication origins, thus modifying the phenotype of the infected cell in favor of viral genome amplification.     

The plant amino acid mimosine may inhibit initiation at origins of replication in Chinese hamster cells.

An understanding of replication initiation in mammalian cells has been hampered by the lack of mutations and/or inhibitors that arrest cells just prior to entry into the S period. The plant amino acid mimosine has recently been suggested to inhibit cells at a regulatory step in late G1. We have examined the effects of mimosine on cell cycle traverse in the mimosine [corrected]-resistant CHO cell line CHOC 400. When administered to cultures for 14 h after reversal of a G0 block, the drug appears to arrest the population at the G1/S boundary, and upon its removal cells enter the S phase in a synchronous wave. However, when methotrexate is administered to an actively dividing asynchronous culture, cells are arrested not only at the G1/S interface but also in early and middle S phase. Most interestingly, two-dimensional gel analysis of replication intermediates in the initiation locus of the amplified dihydrofolate reductase domain suggests that mimosine may actually inhibit initiation. Thus, this drug represents a new class of inhibitors that may open a window on regulatory events occurring at individual origins of replication.     

A reversible arrest point in the late G1 phase of the mammalian cell cycle

The effects of two different cell cycle inhibitors on the proliferation of human lymphoblastoid cells have been analyzed by flow cytometric techniques. Mimosine, a plant amino acid, reversibly blocks the cell cycle at a point which occurs roughly 2 h before the arrest mediated by aphidicolin, an inhibitor of DNA polymerase alpha activity, which defines the G1/S phase boundary. The levels of thymidine kinase mRNA, which increase at the onset of S phase, are higher in cells blocked with aphidicolin than in cells treated with mimosine whereas the opposite results are obtained in the case of p53 mRNA levels, which are known to be maximal in the late G1 phase. These results indicate that mimosine inhibits cell cycle traverse in the late G1 phase prior to the onset of DNA synthesis and identifies a previously undefined reversible cell cycle arrest point.     

Reactivation of lytic replication from B cells latently infected with Epstein-Barr virus occurs with high S-phase cyclin-dependent kinase activity while inhibiting cellular DNA replication

Productive infection and replication of herpesviruses usually occurs in growth-arrested cells, but there has been no direct evidence in the case of Epstein-Barr virus (EBV), since an efficient lytic replication system without external stimuli does not exist for the virus. Expression of the EBV lytic-switch transactivator BZLF1 protein in EBV-negative epithelial tumor cell lines, however, is known to arrest the cell cycle in G(0)/G(1) by induction of the tumor suppressor protein p53 and the cyclin-dependent kinase (CDK) inhibitors p21(WAF-1/CIP-1) and p27(KIP-1), followed by the accumulation of a hypophosphorylated form of the Rb protein. In order to determine the effect of the onset of lytic viral replication on cellular events in latently EBV-infected B LCLs, a tightly controlled induction system of the EBV lytic-replication program by inducible BZLF1 protein expression was established in B95-8 cells. The induction of lytic replication completely arrested cell cycle progression and cellular DNA replication. Surprisingly, the levels of p53, p21(WAF-1/CIP-1), and p27(KIP-1) were constant before and after induction of the lytic program, indicating that the cell cycle arrest induced by the lytic program is not mediated through p53 and the CDK inhibitors. Furthermore, although cellular DNA replication was blocked, elevation of cyclin E/A expression and accumulation of hyperphosphorylated forms of Rb protein were observed, a post-G(1)/S phase characteristic of cells. Thus, while the EBV lytic program promoted specific cell cycle-associated activities involved in the progression from G(1) to S phase, it inhibited cellular DNA synthesis. Such cellular conditions appear to especially favor viral lytic replication.     

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.     

Nutrient-specific effects in the coordination of cell growth with cell division in continuous cultures of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Cell cycle progression of Saccharomyces cerevisiae cells was monitored in continuous cultures limited for glucose or nitrogen. The G1 cell cycle phase, before initiation of DNA replication, did not exclusively expand when growth rate decreased. Especially during nitrogen limitation, non-G1 phases expanded almost as much as G1. In addition, cell size remained constant as a function of growth rate. These results contrast with current views that growth requirements are met before initiation of DNA replication, and suggest that distinct nutrient limitations differentially impinge on cell cycle progression.     

Epidermal growth factor stimulates proliferation and DNA synthesis in ciliate cells

We studied the effect of murine epidermal growth factor on cell proliferation and DNA synthesis in macronuclei of ciliate Tetrahymena pyriformis G1. Mitogenic effect of epidermal growth factor on proliferation-induced tetrahymena cells has been revealed. This effect is due to the induced progression of cells at G1 and, consequently, their earlier entering DNA synthesis phase of the first cell cycle. Epidermal growth factor had no mitogenic effect on the resting cells from stationary culture (G0 phase) whose development is independent of the growth factors in the medium.     

Elevated intracellular concentrations of cyclic AMP inhibited serum-stimulated, density-arrested BALB/c-3T3 cells in mid G1

The stimulation of DNA synthesis in quiescent, density-arrested BALB/c-3T3 cells by platelet-derived growth factor in plasma-supplemented medium was inhibited by the presence of isobutylmethylxanthine (IBMX) and cholera toxin, although neither IBMX or cholera toxin when used alone inhibited the stimulation of DNA synthesis. The cells were reversibly inhibited in mid G1 at a point 6 hr prior to the initiation of DNA synthesis. The inhibition of cell cycle traverse was associated with a 10-15 fold increase in cellular cyclic AMP concentration over basal levels. The reversal of this inhibition by removal of IBMX was correlated with a dramatic decrease in cyclic AMP levels. The traverse of G1 and the initiation of DNA synthesis after release from the cholera toxin and IBMX inhibition was dependent on the presence of plasma in the medium. Either somatomedin C (10-20 ng/ml) or insulin (10(-6)-10(-5) M) completely replaced the plasma requirement for late G1 progression and entry into S phase. Once the inhibited cells were released from the IBMX and cholera toxin block a subsequent increase in cyclic AMP did not prevent entry into S phase. The presence of cholera toxin alone inhibited the stimulation of human dermal fibroblasts. The elevation of intracellular cyclic AMP levels in the human dermal fibroblasts by cholera toxin was two to three fold greater than that found in the BALB/c-3T3 cells in the presence of cholera toxin and the IBMX.     

The human cytomegalovirus UL82 gene product (pp71) accelerates progression through the G1 phase of the cell cycle

As viruses are reliant upon their host cell to serve as proper environments for their replication, many have evolved mechanisms to alter intracellular conditions to suit their own needs. For example, human cytomegalovirus induces quiescent cells to enter the cell cycle and then arrests them in late G(1), before they enter the S phase, a cell cycle compartment that is presumably favorable for viral replication. Here we show that the protein product of the human cytomegalovirus UL82 gene, pp71, can accelerate the movement of cells through the G(1) phase of the cell cycle. This activity would help infected cells reach the late G(1) arrest point sooner and thus may stimulate the infectious cycle. pp71 also induces DNA synthesis in quiescent cells, but a pp71 mutant protein that is unable to induce quiescent cells to enter the cell cycle still retains the ability to accelerate the G(1) phase. Thus, the mechanism through which pp71 accelerates G(1) cell cycle progression appears to be distinct from the one that it employs to induce quiescent cells to exit G(0) and subsequently enter the S phase.     

Regulation of the initiation step of DNA replication by cyclin-dependent kinases

Cyclin-dependent kinases (CDKs) play a central role in the regulation of cell cycle progression in eukaryotes. The onset of S phase, the initiation of chromosomal DNA replication, is a major cell cycle event that is regulated by CDKs. Eukaryotic chromosomal DNA replication is highly regulated and occurs as a two-step reaction. The first reaction, known as licensing, is essential for DNA replication by making cell replication competent and occurs in G1 phase. Once cells enter S phase, licensed chromosomes initiate DNA replication through the action of two conserved protein kinases, S phase-specific CDK and Cdc7-Dbf4 (or Dbf4-dependent kinase). Our understanding of the regulatory mechanisms of DNA replication in model eukaryotes has advanced considerably in the past decade. In this review, we overview the regulation of DNA replication in the eukaryotic cell cycle, focusing specifically on how CDKs regulate the initiation step of DNA replication.