Inhibition of cellular transition from G1-resting to G1-prereplicative phase by aminonucleoside of puromycin.

Human embryonic lung fibroblasts (IMR-90 and WI-38) were arrested in the G1 phase of the cell cycle by serum deprivation and high population density. Within 1 hr after the addition of medium containing fresh serum, these cells showed an increase in rRNA synthesis. The inclusion of 100 micrograms per ml aminonucleoside of puromycin (AMS) in the fresh medium eliminated the serum stimulation of rRNA synthesis and prevented the cells from making the G1-resting phase to G1-prereplicative phase transition. AMS also prevented the synthesis of HnRNA normally found within 10 hr after serum stimulation. Serum-stimulated RNA synthesis in starved, SV-40 transformed fibroblasts (WI-38-VA-13 cells) was inhibited, but not completely prevented, by AMS indicating that transformed cells may produce specific RNA's that are not AMS-sensitive and that may be responsible for the failure of transformed cells to be arrested in G1.     

Isoprenoids and astroglial cell cycling: diminished mevalonate availability and inhibition of dolichol-linked glycoprotein synthesis arrest cycling through distinct mechanisms.

Primary astroglial cultures were used to compare the relationships to cell cycling of dolichol-linked glycoprotein synthesis, and of availability of mevalonate, the precursor of dolichol and other isoprenoid lipids. With shift-up to 10% serum (time 0) after 48 h of serum depletion, the proportion of cells in S phase (bromodeoxyuridine immunofluorescence) remained under 15% for 12 h, then increased by 20 h to 72 +/- 10%; DNA synthetic rates (thymidine incorporation) increased 5-fold. S phase transition was prevented by addition at 10-12 h of tunicamycin, an inhibitor of transfer of saccharide moieties to dolichol. Mevinolin, an inhibitor of mevalonate biosynthesis, also blocked cycle progression when added at this time. However, mevinolin markedly inhibited the isoprenoid pathway, as reflected by over 90% reduction of sterol synthesis, without inhibiting net glycoprotein synthesis. Removal of mevinolin after a 24 h exposure delayed S phase until 48 h, following recovery of sterol synthesis, even though kinetics of glycoprotein synthesis were unaffected. Tunicamycin removal after 24 h spared sterol synthesis, but caused delay of S phase until 72 h, following recovery of glycoprotein synthesis. In mevinolin-treated cultures, S phase transition was restored by 1 h of exposure to mevalonate at 10 h, although cycling was thereby rendered sensitive to inhibition by cycloheximide and by tunicamycin. Cell cycle progression following hydroxyurea exposure and release was unaffected by mevinolin, tunicamycin, or cycloheximide. Thus, in these developing astroglia, mevalonate and its isoprenoid derivatives have at least two cell cycle-specific roles: dolichol-linked glycoprotein synthesis is required at or before the G1/S transition, while a distinct mevalonate requirement is apparent also in late G1.     

Cell proliferation and cell cycle dependent changes in the methylthioadenosine phosphorylase activity in mammalian cells

The objective of this study is to investigate the activity of methylthioadenosine phosphorylase (MTA-Pase) in mammalian cells stimulated by serum to proliferate and during their cell cycle. A direct correlation between growth rate and MTA-Pase activity in chinese hamster ovary (CHO) cells was observed. High MTA-Pase activity was observed during the exponential growth phase followed by a low enzyme activity during plateau phase of growth. To understand whether the fluctuations in the enzyme activity was cell cycle dependent, initially the activity of MTA-Pase was studied in plateau phase (G0) CHO cells as they synchronously go into S phase upon plating in fresh medium. The MTA-Pase activity in G0 cells before initiation of growth was 10.3 n.mol/mg protein/30'. A peak activity of 16.0 n.mol/mg/30 min was found at 12 hr after stimulation of proliferation by serum. These results indicate a peak MTA-Pase activity between 10-12 hr after stimulation of proliferation coinciding with the initiation of DNA synthesis. The activity of the enzyme slowly decreased as the cells completed their DNA synthesis. To understand whether these fluctuations are cell cycle specific, HeLa cells were synchronized in different phases and MTA-Pase activity was studied. The specific activities of the enzyme were 2.76, 2.99, 3.97, 3.28 and 3.65 n.moles/mg/30 min. in mitosis, early G1, late G1, S and G2 phases of the cell cycle respectively. These results indicate that MTA-Pase activity peaks in late G1 phase before the initiation of DNA synthesis, similar to the polyamine biosynthetic enzymes and might play a role in the initiation of DNA synthesis by salvage of adenine into nucleotide pools.     

BrdU-Hoechst flow cytometry reveals regulation of human lymphocyte growth by donor-age-related growth fraction and transition rate

An improved BrdU-Hoechst flow assay was applied to cell kinetic studies of human lymphocyte cultures during a 24-96 hr interval after PHA stimulation. The assay shows that the duration of the initial lag phase and the proportions of noncycling cells increase as a function of donor age, whereas the rates of transition from each cell cycle compartment to the next decrease. Cell cycle arrest occurs in the first S and G2 phase after stimulation of lymphocytes from a 75-year-old donor but not from younger donors. The data are consistent with several models of cell cycle kinetics, so long as these models are modified to include a fraction of noncycling cells in each cell cycle compartment.     

Inhibition of growth of ASL-1w murine leukemia cells by anti-thymus leukemia antigen (TL) serum in the absence of complement.

Previous studies have shown that the cell surface expression of thymus leukemia antigen (TL) on ASL-1w leukemia cells varies with the progression of the cells through the growth cycle. Expression of TL is maximal in S phase, and its quantitative expression varies directly with DNA synthesis. In the present study, the effect of anti-TL serum on the growth of ASL-1w cells was examined. The antiserum, tested in the absence of complement, affected the growth of these cells in biphasic manner. When the antiserum concentration was 0.1% or greater, there was a rapid decline in the rate of DNA synthesis, and after 5 to 7 hr, cell death. When the antiserum concentration was 0.067% or less, the decline in the rate of synthesis of DNA did not become apparent until 5 to 6 hr after treatment. Under these conditions, there was approximately a 20% increase in cell number after 24 hr of culture. The hypothesis that treatment of ASL-1w cells with the lesser concentration of anti-TL serum blocks the cells in G2 phase of the cell cycle is discussed.     

Effect of ouabain on growth regulation by serum components in Balb/c-3T3 cells: inhibition of entry into S phase by decreased protein synthesis

The effect of inhibition of the cell membrane Na+-K+ pump on the Balb/c-3T3 cell growth cycle was studied. Inhibition of the Na+-K+ pump resulted in a dose-dependent reduction of intracellular K+ concentration ((K+)i). However, inhibition of protein synthesis in Go/G1 and of subsequent entry into S phase occurred only after (K+)i fell below a critical threshold (50-60 mmoles/liter). Thus, when the (K+)i falls below a critical threshold, protein synthesis is inhibited, preventing cells from entering the S phase. The platelet-derived growth factor (PDGF) induces cells to become "competent" to traverse the cell cycle; the platelet-poor plasma component of serum allows competent cells to progress through G0/G1 and enter S phase. Inhibition of the Na+-K+ pump did not prevent the induction of competence by PDGF, but it did reversibly inhibit plasma-mediated events in early G0/G1. Similarly, cycloheximide inhibited plasma-mediated events but did not prevent PDGF-induced competence. Thus, protein synthesis may not be required for induction of competence; alternatively, the induction of the competent state may occur in these cells after removal of PDGF and protein synthesis inhibitor. Protein synthesis is required for subsequent plasma-mediated events in G0/G1.     

Uncoupled cell cycle without mitosis induced by a protein kinase inhibitor, K-252a

The staurosporine analogues, K-252a and RK-286C, were found to cause DNA re-replication in rat diploid fibroblasts (3Y1) without an intervening mitosis, producing tetraploid cells. Analysis of cells synchronized in early S phase in the presence of K-252a revealed that initiation of the second S phase required a lag period of 8 h after completion of the previous S phase. Reinitiation of DNA synthesis was inhibited by cycloheximide, actinomycin D, and serum deprivation, but not by Colcemid, suggesting that a functional G1 phase dependent on de novo synthesis of protein and RNA is essential for entry into the next S phase. In a src-transformed 3Y1 cell line, as well as other cell lines, giant cells containing polyploid nuclei with DNA contents of 16C to 32C were produced by continuous treatment with K-252a, indicating that the agent induced several rounds of the incomplete cell cycle without mitosis. Although the effective concentration of K-252a did not cause significant inhibition of affinity-purified p34cdc2 protein kinase activity in vitro, in vivo the full activation of p34cdc2 kinase during the G2/M was blocked by K-252a. On the other hand, the cyclic fluctuation of partially activated p34cdc2 kinase activity peaking in S phase still continued. These results suggest that a putative protein kinase(s) sensitive to K-252a plays an important role in the mechanism for preventing over-replication after completion of previous DNA synthesis. They also suggest that a periodic activation of p34cdc2 is required for S phases in the cell cycle without mitosis.     

Butyrate inhibits mouse fibroblasts at a control point in the G1 phase

Butyrate block 3T6 cells in the G1 phase of the cell cycle approximately 5--6 h prior to the start of the S phase. Serum factors are required before as well as after the butyrate-sensitive steps in G1 in order to allow cells to start DNA synthesis. 3T6 cells infected with SV40 or with polyoma virus are also blocked at the same stage in G1 in the presence of the fatty acid. However, events before as well as after the butyrate-sensitive step do not require serum in virus-infected cells. The sensitivity of the initiation of cellular DNA synthesis to increasing concentrations of butyrate is the same for serum-stimulated or for virus-infected cells. A similar and parallel effect on DNA synthesis is observed if cells are incubated in the presence of very small amounts of cycloheximide. After release of the cycloheximide-induced G1 arrest about 4--6 h have to pass before cells enter the S phase. Cells stably transformed by SV40 are considerably more resistant to low cycloheximide concentrations and to butyrate. These data are discussed in the light of the hypothesis that both low concentrations of cycloheximide and sodium butyrate block cells at a control point in G1 by interference with the synthesis of one or more rapidly turning over, cell cycle-specific proteins.     

G1 and S phase mammalian cells synthesize histones at equivalent rates

To determine the effect of cell cycle position on protein synthesis, synchronized cell populations were metabolically labeled and the synthesis of the basic proteins, including histones, was examined by two-dimensional gel electrophoresis. Exponentially growing S49 mouse lymphoma or Chinese hamster ovary (CHO) cells were separated into G1 and S phase populations by centrifugal elutriation, selective mitotic detachment, fluorescence-activated cell sorting, or a combination of these, and pulse-labeled with radiolabeled amino acids. The histone proteins, both free and chromatin-bound, were completely resolved from some 300 other basic polypeptides in whole-cell lysates by a modification of the NEPHGE technique of O'Farrell, Goodman and O'Farrell (1977). Comparisons of matched autoradiograms from samples of G1 and S phase labeled cells revealed an equivalent rate of histone synthesis through the cell cycle of both S49 and CHO cells. Nuclei isolated from G1 phase S49 cells that were pulse-labeled contained between 13 and 15% of the newly synthesized nucleosomal histones present in S phase nuclei. Nuclei prepared from G1 phase cells that were pulse-labeled and then chased for 5 hr contained more than 90% of the labeled nucleosomal histones present in wholecell lysates. It therefore seems likely that differential alterations in the rate of histone synthesis do not occur to a significant degree as cells proceed through the cycle, but the association of newly synthesized histones with DNA takes place after the onset of DNA replication.     

Blockage of prereplicative progression by cytochalasin D in serum-stimulated GC-7 cells

When growth-arrested GC-7 cells, a cell line from African green monkey kidney, are stimulated with 10% calf serum, they enter S phase 14-15 h later. Cytochalasin D at 0.6 micrograms/ml blocks the entrance into S phase, and inhibits, though only partially, the increase in protein synthesis after serum stimulation. Since partial inhibition of protein synthesis by cycloheximide interferes with accumulation of labile proteins and thus blocks the entrance of serum-stimulated cells into S phase, the effects of these two inhibitors are compared. Cytochalasin D at lower concentrations reduced the rate of entry into S phase without affecting the length of the prereplicative phase, whereas cycloheximide extended the prereplicative phase dose dependently without affecting the rate of entry into S phase. Cytochalasin D affected neither individual [35S]methionine-labeled spots on two-dimensional polyacrylamide-gel nor degradation of cellular proteins. These results indicate that cytochalasin D, though it interferes with protein synthesis, blocks prereplicative progression of serum-stimulated GC-7 cells in a different manner than cycloheximide.     

Late G1 amino acid restriction point in human dermal fibroblasts

Human dermal fibroblasts arrested in G0 by maintenance in medium supplemented with 0.1% serum were not restimulated to divide when fresh medium containing 10% dialyzed serum but lacking group B amino acids (cystine, isoleucine, lysine, phenylalanine and tyrosine) was added. Unlike rodent cells, the addition of fresh serum-supplemented medium lacking only isoleucine did not cause a growth arrest. The amino acid sensitive growth arrest in human fibroblasts was dependent both on presynchronization in G0 as well as a prestarvation for amino acids prior to stimulation with high serum. When cells were restimulated in the absence of amino acids, they arrested predominantly in G1, although a small percentage of cells entered early S phase. When medium containing a complete complement of amino acids was then added, cells initiated DNA synthesis following a minimum lag of 2-3 hr. Growth arrested cells initiated DNA synthesis even when complete unsupplemented medium was added, although the addition of high concentrations of insulin or 10% serum increased the rate of entry.     

Effects of inhibition of RNA or protein synthesis on CHO cell cycle progression

Chinese hamster ovary (CHO) cells, synchronized by selective detachment at mitosis, were treated with various concentrations of actinomycin D (AMD) or cycloheximide (CHX) either immediately, or 1, 2, or 3 hr after mitosis. Since the minimum duration of G₁ phase in these cultures was 3.4 hr, the addition of RNA or protein synthesis inhibitors took place at the beginning, first third, second third, or end (G₁–S boundary) of G₁ phase. The kinetics of exit from G₁ phase, the rate and extent of traverse of S phase, and the reaccumulation of RNA were estimated under each set of growth conditions by flow cytometry of acridine orange-stained cells. A mathematical model was constructed to describe the trajectories of the cell populations with respect to their increase in RNA and DNA content in the absence or presence of the inhibitor. The chronologic synchrony imposed on the CHO cell population began to decay within 3 hr, resulting in stochastic entrance of cells into S phase in the absence of inhibitor. Addition of AMD or CHX at 0, 1, 2, or 3 hr after mitosis, regardless of the inhibitor concentration, did not provide evidence of a critical restriction point in G₁ beyond which cells were committed to enter S phase and were no longer sensitive to moderate suppression of RNA or protein synthesis. The observed kinetics of cell entrance into and traverse of S phase were consistent with an inherently heterogenous response to serum stimulation occurring at or just after cell division.     

The stimulation of the initiation of DNA synthesis by fibroblast growth factor in swiss 3T3 cells: Interactions with hormones during the pre-replicative phase

Fibroblast Growth Factor (FGF) stimulates quiescent Swiss 3T3 cells to initiate DNA synthesis and divide. Cells begin to enter the S-phase after a lag of 13–15 hr, and the rate of initiation of DNA synthesis in the population can be quantified by a first order rate constant, k. A subsaturating concentration of FGF may establish the lag phase, while the value of k is dependent on the FGF concentration present during the second half of the lag phase. Insulin and hydrocortisone enhance the effect of FGF by increasing k without changing the lag phase, and they can act when added at any time after FGF. Prostaglandin E₁ (PGE₁) causes a decrease in k and a lengthening of the lag phase, and acts only when added during the first 8 hr. None of these agents stimulate DNA synthesis in the absence of FGF. These results show that the stimulation of growth by FGF follows the same basic pattern as was previously shown with Prostaglandin F_2α (PGF_2α). However, since hydrocortisone inhibits stimulation by PGF_2α when added during the first 4 hr of the lag phase, there are clearly differences in some events stimulated by the two growth factors.     

Advance toward S phase and retreat toward deeper "G0" states in resting 3Y1 cells with environmental changes

To elucidate conditions which affect the lag time for resting cells to enter S phase after serum stimulation, we used a wild-type 3Y1 rat fibroblast line and four temperature-sensitive mutants of 3Y1 (3Y1tsD123, 3Y1tsF121, 3Y1tsG125, and 3Y1tsH203). Among these five lines, in only tsG125 cells was there an obviously prolonged lag time with increase in time in resting state at 33.8 degrees C. The resting wild-type 3Y1 cells, preexposed to 39.8 degrees C, also showed a prolongation of lag time. The prolongation in tsG125 had a certain limit. Preexposure to 39.8 degrees C before serum stimulation accelerated such prolongation in tsG125 to its limit, but did not change the limit, per se. Resting tsG125 cells stimulated by serum at 39.8 degrees C, did not enter S phase, yet they did advance toward S phase. When they were kept at 39.8 degrees C, they retreated toward a deeper resting state ("G0") with time. These retreats correlated with the decrease in stimulating activity in the culture media. About 20% of the resting tsG125 cells stimulated by serum at 39.8 degrees C were committed to enter S phase, when the extent of commitment was examined at 33.8 degrees C. Most of the tsG125 cells committed at 33.8 degrees C did not enter S phase, when the extent of commitment was examined at 39.8 degrees C. More cells were committed after stimulation at 33.8 degrees C than at 39.8 degrees C, when the test was done at 33.8 degrees C. We suggest that resting cells may be reversibly changed within range of resting states, in either direction, that is, advance toward S phase or retreat toward deeper "G0." These changes may be determined by alterations in the balance between synthesis and decay of the preparedness for the initiation of DNA synthesis caused by cellular response to environmental changes (e.g., medium activity, temperature, etc.). The ts defect in tsG125 may affect the cell cycle progression, both before and after commitment by serum.     

Cell cycle parameters of adult rat hepatocytes in a defined medium. A note on the timing of nucleolar DNA replication

Hepatocytes, isolated from adult (250-350 g) rats, attached and survived well in primary culture on highly diluted (less than 1 microgram/cm2) collagen gel in a synthetic medium without serum or hormones. About 20% of the cells "spontaneously" entered S phase during the first 4 days of culturing, and mitoses were easily demonstrated at the near physiological concentration (1.25 mM) of Ca++ prevailing in the medium. Cultures given 9 nM epidermal growth factor (EGF) and 20 nM insulin 20 h after inoculation showed vigorous DNA synthesis and mitotic activity. Autoradiography of such cells exposed to [3H]thymidine allowed the determination of the following cell cycle parameters: Lag period from EGF/insulin stimulation till onset of increased DNA synthesis, 17 h; rate of entry into S phase (kG1/S), 0.028/h; duration of S phase, 8.4 h; duration of G2 phase, 2.7 h. The peak DNA synthesis (pulse labelling index, 24%) and peak mitotic activity (mitotic index, 1.7%) occurred 35 and 43 h, respectively, after the stimulation with EGF/insulin. These values are comparable to those reported during the in vivo compensatory hyperplasia following partial hepatectomy of adult rats. A marked variation of the intranuclear [3H]thymidine pulse labelling pattern was noted: During the first 1.5 h of the S phase, the labelling was extranucleolar and during the last 1.5 h chiefly nucleolar. The cells survived well in the absence of glucocorticoid, whose effect on cell cycle parameters therefore could be studied. Dexamethasone (25-250 nM) did not appreciably affect the durations of S phase and G2 phase or the pattern of preferential extranucleolar and nucleolar DNA synthesis within the S phase.     

Macrophage-mediated cytostatic activity blocks lymphoblast cell cycle progression independently in both G1 phase and S phase

Recent work has shown that macrophage-mediated cytostatic activity inhibits cell cycle traverse in G1 and/or S phase of the cell cycle without affecting late S, G2, or M phases. The present report is directed at distinguishing between such cytostatic effects on G1 phase or S phase using the accumulation of DNA polymerase alpha as a marker of G1 to S phase transition. Quiescent lymphocytes stimulated with concanavalin A undergo a semisynchronous progression from G0 to G1 to S phase with a dramatic increase in DNA polymerase alpha activity between 20 and 30 hr after stimulation. This increase in enzyme activity was inhibited, as was the accumulation of DNA, when such cells were cocultured with activated murine peritoneal macrophages during this time interval. However, if mitogen-stimulated lymphocytes were enriched for S-phase cells by centrifugal elutriation and cocultured with activated macrophages for 4-6 hr, DNA synthesis was inhibited but the already elevated DNA-polymerase activity was unaffected. Similar results were obtained when a virally transformed lymphoma cell line was substituted as the target cell in this assay. These results show that both G1 and S phase of the cycle are inhibited and suggest that inhibition of progression through the different phases may be accomplished by at least two distinct mechanisms.     

Mode of estrogen action on cell proliferation in CAMA-1 cells: II. Sensitivity of G1 phase population

The mammary cancer cell line CAMA-1 synchronized at the G1/S boundary by thymidine block or at the G1/M boundary by nocodazole was used to evaluate 1) the sensitivity of a specific cell cycle phase or phases to 17 beta-estradiol (E2), 2) the effect of E2 on cell cycle kinetics, and 3) the resultant E2 effect on cell proliferation. In synchronized G1/S cells, E2-induced 3H-thymidine uptake, which indicated a newly formed S population, was observed only when E2 was added during, but not after, thymidine synchronization. Synchronized G2/M cells, enriched by Percoll gradient centrifugation to approximately 90% mitotic cells, responded to E2 added immediately following selection; the total E2-treated population traversed the cycle faster and reached S phase approximately 4 hr earlier than cells not exposed to E2. When E2 was added during the last hour of synchronization (ie, at late G2 or G2/M), or for 1 hr during mitotic cell enrichment, a mixed response occurred: a small portion had an accelerated G1 exit, while the majority of cells behaved the same as controls not incubated with E2. When E2 addition was delayed until 2 hr, 7 hr, or 12 hr following cell selection, to allow many early G1 phase cells to miss E2 exposure, the response to E2 was again mixed. When E2 was added during the 16 hr of nocodazole synchronization, when cells were largely at S or possibly at early G2, it inhibited entry into S phase. The E2-induced increase or decrease of S phase cells in the nocodazole experiments also showed corresponding changes in mitotic index and cell number. These results showed that the early G1 phase and possibly the G2/M phase are sensitive to E2 stimulation, late G1, G1/S, or G2 are refractory; the E2 stimualtion of cell proliferation is due primarily to an increased proportion of G1 cells that traverse the cell cycle and a shortened G1 period, E2 does not facilitate faster cell division; and estrogen-induced cell proliferation or G1/S transition occurs only when very early G1 phase cells are exposed to estrogen. These results are consistent with the constant transition probability hypothesis, that is, E2 alters the probability of cells entering into DNA synthesis without significantly affecting the duration of other cell cycle phases. Results from this study provide new information for further studies aimed at elucidating E2-modulated G1 events related to tumor growth.     

Modification of X-Ray-Induced Killing of HeLa S3 Cells by Inhibitors of DNA Synthesis

After irradiation of HeLa S3 cells with 220 kv x-rays during G1, treatment with any of six inhibitors of DNA synthesis results in the progressive enhancement of cell killing (loss of colony-forming ability). Incubation with hydroxyurea, cytosine arabinoside, or hydroxylamine reduces survival five- to twentyfold in about 8 hr, following an x-ray dose of 400 rads. In contrast, treatment with 5-fluorodeoxyuridine, deoxyadenosine, or thymidine after this same dose reduces survival less than twofold during a comparable time interval. These differences occur at drug concentrations which reduce the rate of DNA synthesis by at least 95% (except in the case of hydroxylamine, which inhibits DNA synthesis to a smaller extent), but which kill no unirradiated cells during the treatment periods. When inhibition of DNA synthesis with either hydroxyurea or cytosine arabinoside is reversed by addition of appropriate precursors of DNA, the enhancement is abolished. With hydroxyurea, the rate of cell killing is dependent on the dose of x-rays previously administered, and the extent of enhancement seems to be related to the drug concentration. Imposition of a delay between irradiation and addition of hydroxyurea does not abolish the enhancement effect, but instead causes a proportional lag in its inception. Postirradiation treatment of S phase cells with either hydroxyurea or cytosine arabinoside also enhances killing. Furthermore, unlike early G1 cells, S cells (and, as shown previously, cells blocked at the G1-S transition) are sensitized by preirradiation exposure to hydroxyurea.     

Cytoplasmic regulation of two G1-specific temperature-sensitive functions

tsAF8 and ts13 cells are temperature-sensitive (ts) mutants of BHK cells that specifically arrest, at nonpermissive temperature, in the G1 phase of the cell cycle. These two mutants can complement each other. Both cell lines can be made quiescent by serum deprivation (G0). When subsequently stimulated by serum, they can enter S phase at 34 degrees C but not at 39.5 degrees-40.6 degrees C. We have used these mutants to determine whether the nucleus is needed during the G0 leads to S transition for the expression of the G1 ts functions. For this purpose, we fused cytoplasts of G0-tsAF8 with whole ts13 cells in G0, and cytoplasts of G0-ts13 with whole tsAF8 cells in G0. Serum stimulation at the nonpermissive temperature induced DNA synthesis in both types of such fusion products. No DNA synthesis was induced by serum stimulation at the nonpermissive temperature in fusion products constructed between either G0-tsAF8 cytoplasts and whole G0-tsAF8 cells or G0-ts13 cytoplasts and whole G0-ts13 cells. These results demonstrate that the information for these two ts functions, which are required for entry of serum-stimulated cells into the S phase, are already present in the cytoplasm of G0 cells--that is, before serum stimulation commits them to the transition from the nonproliferating to the proliferating state.     

Regulation of thymidylate synthase enzyme synthesis in 5-fluorodeoxyuridine-resistant mouse fibroblasts during the transition from the resting to growing state

Thymidylate synthase (TS) activity is very low in resting mouse 3T6 fibroblasts but increases sharply in growth-stimulated cells at about the same time the cells enter S phase. To study the mechanism responsible for the increase in TS level, we isolated a 5-fluorodeoxyuridine (5-FdUrd)-resistant cell line (LU3-7) that overproduces TS and its mRNA about 50-100-fold. In this paper we show that the LU3-7 cells were able to rest in the G0 state of the cell cycle when maintained in medium containing 0.5% serum. When the serum concentration was increased to 10%, the resting cells reentered the cell cycle and began DNA replication about 12 hr later. TS activity remained at the resting level until DNA replication began, then increased at later times. The increase was not affected when the cells were stimulated in the presence of DNA synthesis inhibitors. The rate of synthesis of TS (as determined in a pulse-labeling experiment) remained at the resting level for the first 10 hr following stimulation, then increased 8-9-fold by 25 hr following serum stimulation. The half-life of TS in growing LU3-7 cells was measured in a pulse-chase experiment and found to be greater than 24 hr. Therefore the increase in TS activity was primarily due to an increase in the rate of synthesis of the enzyme. Since TS gene expression appears to be regulated in a similar manner in LU3-7 cells and in the parental 3T6 cells, the LU3-7 cells should be a good model system for detailed analysis of the mechanism for regulating TS gene expression in mammalian cells.