Evidence for endogenous polypeptide-mediated inhibition of cell-cycle transit in human diploid cells

Previous studies have shown that the senescent phenotype is dominant with respect to DNA synthesis in fusions between late passage and actively replicating human diploid fibroblasts. Brief postfusion treatments with the protein synthesis inhibitor cycloheximide (CHX) or puromycin have been found to significantly delay (by 24-48 h) the inhibition of entry into DNA synthesis of young nuclei in heterokaryons after fusion with senescent cells. A significant fraction of the senescent nuclei incorporated tritiated thymidine in CHX-treated heterokaryons. The optimal duration of exposure to CHX was 1-3 h immediately after fusion, although treatments beginning as late as 9 h after fusion elevated the heterokaryon labeling index. Prefusion treatments with CHX were without a significant effect. These results are consistent with the interpretation that regulatory cell cycle inhibitor(s) which are dependent upon protein synthesis may be present in heterokaryons between senescent and actively replicating cells.     

DNA synthesis in polyoma virus infection. V. Kinetic evidence for two requirements for protein synthesis during viral DNA replication.

Protein synthesis in polyoma virus-infected cells was inhibited by 99% within 4 min after exposure to 10 mug of cycloheximide per ml. Subsequent to the block in protein synthesis, the rate of viral DNA synthesis declined via inhibition of the rate of initiation of new rounds of genome replication (Yu and Cheevers, 1976). This process was inhibited with complex kinetics: within 15 min after the addition of cycloheximide, the rate of formation of closed-circular viral DNA was reduced by about one-half. Thereafter, DNA synthesis in cycloheximide-treated cells declined more slowly, reaching a level of 10% of untreated cells only after approximately 2 h. Protein synthesis was also required for normal closure of progeny form I DNA: in the presence of cycloheximide, DNA synthesis was diverted from the production of form I to form Ic, a monomeric closed-circular DNA component deficient in superhelical turns (Yu and Cheevers, 1976). Form I is replaced by Ic with first-order exponential kinetics. It is concluded that at least two proteins are involved in the control of polyoma DNA replication. One is apparently a stoichiometric requirement involved in the initiation step of viral DNA synthesis, since this process cannot be maintained at a normal rate for more than a few minutes in the absence of protein synthesis. The second protein requirement, governing the closure of newly synthesized progeny DNA, is considered distinct from the "initiation" protein on the basis of the kinetic data.     

Deoxyribonucleic Acid Replication in Simian Virus 40-Infected Cells IV. Two Different Requirements for Protein Synthesis During Simian Virus 40 Deoxyribonucleic Acid Replication

The replication of simian virus 40 (SV40) deoxyribonucleic acid (DNA) was inhibited by 99% 2 hr after the addition of cycloheximide to SV40-infected primary African green monkey kidney cells. The levels of 25S (replicating) and 21S (mature) SV40 DNA synthesized after cycloheximide treatment were always lower than those observed in an infected untreated control culture. This is consistent with a requirement for a protein(s) or for protein synthesis at the initiation step in SV40 DNA replication. The relative proportion of 25S DNA as compared with 21S viral DNA increased with increasing time after cycloheximide treatment. Removal of cycloheximide from inhibited cultures allowed the recovery of viral DNA synthesis to normal levels within 3 hr. During the recovery period, the ratio of 25S DNA to 21S DNA was 10 times higher than that observed after a 30-min pulse with (3)H-thymidine with an infected untreated control culture. The accumulation of 25S replicating SV40 DNA during cycloheximide inhibition or shortly after its removal is interpreted to mean that a protein(s) or protein synthesis is required to convert the 25S replicating DNA to 21S mature viral DNA. Further evidence of a requirement for protein synthesis in the 25S to 21S conversion was obtained by comparing the rate of this conversion in growing and resting cells. The conversion of 25S DNA to 21S DNA took place at a faster rate in infected growing cells than in infected confluent monolayer cultures. A temperature-sensitive SV40 coat protein mutation (large-plaque SV40) had no effect on the replication of SV40 DNA at the nonpermissive temperature.     

Regulation of cell-cycle initiation in yeast by nutrients and protein synthesis.

Arrested Saccharomyces cerevisiae cells initiate the cell cycle in an asynchronous mode. The asynchronous manner of cycle initiation generates variability in cell-cycle times of individual cells. Limiting concentrations of adenine, methionine or histidine regulate the rate of cycle initiation in auxotrophs. A sigmoidal curve of rate vs. concentration is obtained for each of the three substances. Moreover, the three curves have similar Hill coefficients of 2.4, suggesting that a common intermediate requiring adenine, methionine and histidine regulates cell-cycle initiation in yeast. Low concentrations of cycloheximide reduce the rate of cycle initiation of arrested cells that are released from the block in a similar way as limiting nutrients. It thus appears that the common intermediate that requires the limiting nutrients depends upon protein synthesis. The rate of cycle initiation is more sensitive to cycloheximide or nutrient limitation than is protein synthesis. It is also affected by limiting nutrients to a much greater extent than is the overall rate of protein accumulation (i.e., net protein synthesis). Hence the mechanism that controls cycle initiation does not depend on the overall synthesis or accumulation of proteins in the cell. It may depend on synthesis of particular proteins whose production or function requires the limiting nutrients. The high sensitivity of cycle initiation to a decrease in the rate of protein synthesis could explain the ability of yeast cells to complete the cycle and arrest at stationary phase upon depletion of medium components. The cells cannot initiate the cycle although their protein synthesis capacity remains sufficiently high to allow traversal of the rest of the cell cycle.     

Erythropoietic progenitors capable of colony formation in culture: response of normal and genetically anemic W-W-V mice to manipulations of the erythron

The macromolecular reguirements for the initiation and maintenance of macronuclear DNA replication were studied in heat synchronized Tetrahymena pyriformis GL-C. Previous work had established that macronuclear S periods could occur in a consecutive fashion without intervening cell divisions during a multiple heat shock treatment, as well as immediately following the synchronized cell divisions. Cycloheximide treatment prior to or during the S period which follows the first synchronized cell division resulted in abolition of the initiation of DNA synthesis or an almost immediate cessation of DNA synthesis in progress. Temporary inhibition of DNA synthesis occurred when cycloheximide was added late in the S period. Treatment with actinomycin D was found to block the initiation of DNA synthesis but did not appreciably affect the continuation of the S period. It was concluded that RNA synthesis was required for the initiation but not the maintenance of DNA replication, whereas protein synthesis was necessary for both processes. The dependency of the initiation of an S period on prior RNA and protein synthesis was also shown to exist when a second consecutive S period was initiated without a preceding cell division. Treatment with actinomycin or cycloheximide prior to a supernumerary S period during a multiple heat shock treatment completely abolished the initiation of DNA synthesis. In T. pyriformis the synthesis of RNA and protein related to the initiation of the S period is tightly coupled to each cycle of DNA replication.     

Regulation of the G1 leads to S phase transition in chick embryo fibroblasts with alpha-keto acids and L-alanine.

Temporal inhibition of protein synthesis with cycloheximide prevents subsequent insulin, but not serum-stimulated DNA synthesis in G1-arrested chick embryo fibroblasts (CEF). The inhibition is measured by the incorporation of 3H-thymidine into acid insoluble material and confirmed by chemical estimate of the DNA content of inhibited and uninhibited cells. Cycloheximide treatment is without effect if the cell cultures are maintained at 4 degrees C while exposed to the drug. Several alpha-keto acids (pyruvate, oxaloacetate, alpha-ketobutyrate) at 0.5-1 mM concentrations restore DNA synthesis in previously inhibited cells when combined with insulin. L-alanine (D-alanine is inert) is even more effective than the keto acids in stimulating DNA synthesis after cycloheximide treatment. Glucose transport was unaffected by cycloheximide treatment while lactate levels in medium from inhibited, insulin-stimulated CEF were reduced 70% compared to uninhibited counterparts. We speculate that cycloheximide treatment may lead to the decay of a glycolytic enzyme which compromises the ability of inhibited cells to synthesize pyruvate from glucose, and thus induces an exogenous requirement for alpha-keto acid or L-alanine. A serum component(s) with a molecular weight of about 100 permitted insulin-stimulated DNA synthesis in inhibited cells.     

Evidence for differences in the mechanism of cell cycle arrest between senescent and serum-deprived human fibroblasts: Heterokaryon and metabolic inhibitor studies

It has previously been shown that serum-deprived, early passage quiescent human diploid fibroblastlike (HDFL) cells are able to inhibit cycling cells from entry into DNA synthesis upon cell fusion. We have found that the degree of inhibition of DNA synthesis in the heterokaryon correlates with the duration of serum deprivation, which is consistent with the suggestion that serum-deprived cells may enter progressively deeper stages of G₀ as they increase their time in quiescence. In contrast to fusions with senescent cells, in heterokaryons between serum-deprived early passage and cycling young cells transient inhibition of protein synthesis with cycloheximide or inhibition of RNA synthesis with 5–6-dichloro-1-β-D-ribofuranosyl benzimidazole (DRB) did not stimulate nuclear [₃H]-thymidine incorporation. These results suggest that differences may exist in the mechanisms responsible for inhibiting cell cycle progression in senescent vs early passage quiescent HDFL cells.     

DNA synthesis in polyoma virus infection. III. Mechanism of inhibition of viral DNA replication by cycloheximide.

The formation of viral DNA was inhibited in polyoma virus-infected cells in which protein synthesis had been blocked by cycloheximide. The present studies show the following. (i) The pool of replicating viral DNA molecules was reduced in cycloheximide-treated cells by an amount consistent with inhibition of [3-H]thymidine incorporation into viral DNA, whereas the rate of turnover of the replicating population was not affected. (ii) The rate of conversion of replicating molecules into closed-circular DNA was not affected by cycloheximide. (iii) The rate of elongation of nascent viral DNA fragments into strands of unit genome length was unaffected by cycloheximide. It is concluded that viral DNA synthesis is inhibited in the absence of protein synthesis exclusively at the level of initiation of new rounds of genome replication. Replicating molecules already initiated at the time of addition of cycloheximide matured into progeny closed-circular DNA at a normal rate.     

A potent DNA synthesis inhibitor expressed by the immortal cell line SUSM-1

We have previously reported the production of DNA synthesis inhibitor proteins by both quiescent and senescent human diploid fibroblasts. Young, proliferating fibroblasts do not produce such inhibitors, but are capable of responding to either the quiescent or senescent cell DNA synthesis inhibitors. Recently, we have analyzed the immortal cell line SUSM-1 (derived from normal liver fibroblasts following exposure to carcinogen) for inhibitory activity. We have found that SUSM-1 cells produce a factor capable of inhibiting DNA synthesis in young fibroblasts. Crude extracts prepared from SUSM-1 cells inhibit DNA synthesis in a dose-dependent manner at concentrations 10-fold lower than those of either senescent or quiescent fibroblast cell extracts. SUSM-1 cells are incapable of responding to the inhibitor they produce, as are three other immortal human cell lines tested. One immortal cell line, HeLa, does respond to the SUSM-1 inhibitor, though to a lesser degree than observed with normal young fibroblasts. One hypothesis is that the DNA synthesis inhibitor protein(s) of senescent cells plays a role in determining the finite in vitro life span of normal cells. The results reported here suggest that SUSM-1 cells may have escaped senescence through loss of a receptor or cofactor for the inhibitor protein(s).     

Senescent and quiescent cell inhibitors of DNA synthesis : Membrane-associated proteins

Cytoplasts derived from senescent and quiescent human diploid cells inhibit DNA synthesis initiation when fused with cells capable of proliferation. When the cytoplasts were subjected to a variety of conditions (trypsin and cycloheximide treatment and growth on fibronectin), this inhibitory activity was lost, suggesting that the inhibitors involved were proteins associated with the surface membranes of the cells. We have studied the quiescent cell inhibitor in greater detail and determined that surface membrane-enriched preparations isolated from quiescent cells and proteins extracted from these membrane preparations have DNA synthesis-inhibitory activity.     

Entry into S phase is inhibited in two immortal cell lines fused to senescent human diploid cells.

Senescent human diploid cells (HDC) were fused to T98G human glioblastoma cells and to RK13 rabbit kidney cells, and DNA synthesis was analyzed in the heterodikaryons. T98G and RK13 cells are “partially transformed” cell lines that have some characteristics of normal cells, yet are transformed to immortality, i.e., they do not senesce. Previous experiments have shown that “fully transformed” HeLa and SV80 cells induce DNA synthesis in senescent HDC nuclei, whereas normal young HDC do not. Our experiments show that T98G and RK13 cells do not induce DNA synthesis in senescent HDC nuclei. These results demonstrate that the ability to induce DNA synthesis in senescent HDC is not correlated with immortality per se. Our results show further that a T98G cell in S phase at the time of fusion to a senescent HDC will continue to make DNA. However, a T98G cell in G1 phase at the time of fusion is prevented from initiating DNA synthesis. RK13 cells behave similarly to T98G. These results are consistent with the hypothesis that the molecular basis for the senescent phenotype involves a block that prevents cells in G1 phase from entering S phase. Thus, we conclude that the senescent phenotype can be dominant in heterokaryons composed of senescent HDC fused with certain immortal cell lines. To explain the different results obtained with various immortal cell lines, we present a model that suggests that T98G and RK13 cells are immortal because they have lost a normal regulatory factor, whereas HeLa and SV80 are immortal because they have gained a dominant transformation factor.     

Replicon initiation in normal human cells and in ataxia telangiectasia cells: its differential inhibition by cycloheximide and bleomycin

Treatment of normal human fibroblasts (NHFs) with cycloheximide, which inhibits protein synthesis, resulted in partial inhibition of their DNA synthesis, as determined by incorporation of radioactive thymidine and resistance of the cells to subsequent treatment with bleomycin. The effects of treatments of ataxia telangiectasia fibroblasts (ATFs) with cycloheximide and then bleomycin on their DNA synthesis were very similar to those on DNA synthesis of NHFs. The fact that treatment with bleomycin only caused transient inhibition of DNA synthesis within an hour in NHFs but not ATFs was confirmed. Studies by alkali-density gradient centrifugation showed that the cycloheximide mainly inhibited formation of short fragments of DNA in both NHFs and ATFs, as bleomycin does in NHFs. These findings suggest that these two chemicals both inhibit replicon initiation, and thus provide evidence that the genetic defect in ATFs is related to replicon initiation.     

DEPENDENCE OF PERIODIC DNA SYNTHESIS ON PROTEIN SYNTHESIS: DELAY OF DNA SYNTHESIS IN THE EARLY CLEAVAGE STAGE OF SEA URCHIN EMBRYOS TREATED WITH CYCLOHEXIMIDE AND COLCHICINE

The effects of cycloheximide and colchicine on cleavage and syntheses of DNA and proteins in cleaving embryos of the sea urchin, Hemicentrotus pulcherrimus , were examined. Cycloheximide caused delay of cell division with prolongation of the streak stage. Both inhibitors also caused delay in initiation of DNA synthesis. The decrease in the rate and prolongation of the period of DNA synthesis caused by these inhibitors varied with their concentrations and the time of administration. Initiation of DNA synthesis was delayed when cycloheximide was added to suspensions of embryos between the time after preceding DNA synthesis terminated and a definite time before the predicted time of initiation of the next synthesis of DNA, except at the stage of pronuclear fusion. However, when the inhibitor was added after initiation of the synthesis, the latter proceeded normally. Addition of 10 m m cycloheximide immediately after fertilization or 2 m m cycloheximide 60 min before fertilization also delayed DNA synthesis at the stage of pronuclear fusion, indicating that synthesis at this stage also required prior protein synthesis. Colchicine had less inhibitory effect on protein synthesis, but greatly delayed initiation of DNA synthesis and prolonged its duration. These facts suggest that a definite amount of a particular protein must be synthesized and accumulated in each synthetic cycle before initiation of DNA synthesis.     

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.     

Inhibition of DNA synthesis in proliferating human diploid fibroblasts by fusion with senescent cytoplasts

Cytoplasts were prepared from senescent human diploid fibroblasts. The cytoplasts were fused to young human diploid fibroblasts and DNA synthesis was analyzed in the fusion products. DNA synthesis was inhibited (greater than or equal to 40%) in the senescent cytoplast fusion products when compared to unfused young cells or young cytoplasts fused with young cells. These results are consistent with previous experiments that have shown the blockage of DNA synthesis in both nuclei of heterokaryons from fusions of senescent and young human diploid fibroblast cells. Furthermore, these results support the postulate that senescent cells synthesize a specific substance(s), which is present in the cytoplasm of the senescent cell that inhibits DNA synthesis.     

Synthesis of type 2 Adenovirus DNA in the Presence of Cycloheximide

Adenovirus type 2 DNA synthesis, either in permissive human cells or nonpermissive monkey cells, becomes independent of protein synthesis after the appearance of progeny viral DNA. In the presence of cycloheximide, semiconservative replication and initiation of progeny molecules can occur.     

Synthesis of the adenovirus-coded DNA binding protein in infected cells.

Synthesis of the 75K (75K indicates a moleculatr weight of 70,000 to 75,000) DNA binding protein, an early virus-coded protein in adenovirus 2-infected KB cells, and its regulation were studied by using a radioimmune precipitation inhibition assay. The protein was first detected at 4 h postinfection and accumulated at an expoential rate. An arrest of further synthesis (accumulation) was observed at 10 to 11 h postinfection, coinciding with the onset of synthesis of late virion proteins. In contrast, when the infected cells were treated with 25 mug of arabinosyl cytosine per ml to block viral DNA replication, the synthesis of 75K protein did not cease but continue for up to 36 h postinfection. The synthesis of 75K protein in cells after release from a cycloheximide block (2 to 9 h postinfection) was analyzed. Increased amounts of early adenovirus-specific mRNA accumulate in infected cells during a cycloheximide block (Parsons and Green, 1971). However, cycloheximide treatment did not produce increased levels of 75K protein, and an abrupt arrest of 75K protein formation was again observed at the time of synthesis of late virion proteins. Partition of the 75K protein between the nuclear and cytoplasmic fractions during the course of infection was studied. The 75K protein appeared first in the cytoplasm and then in the nucleus after a slight lag. Accumulation of the 75K protein continued both in the cytoplasm and nucleus, with higher levels being found in the cytoplasm.     

DNA replication in mammalian cells. Altered patterns of initiation during inhibition of protein synthesis

The effects of inhibition of protein synthesis by the antibiotics cycloheximide and puromycin on the initiation of DNA replication in mouse L cells were studied. Cellular DNA was pulse labeled with [3H]thymidine of high, then of low specific activity and prepared for fiber autoradiography. Autoradiograms containing multiple (up to four) replication units were analyzed. In control cells, the proportion of replication units that initiated during a 10-min, high specific activity pulse was approximately equal to the proportion initiating immediately before the pulse. The addition of cycloheximide or puromycin at the start of the pulse inhibited the frequency of initiation in that there was a decrease by up to one-third of units initiating during the pulse relative to controls. Replication direction was also altered. Addition of the antibiotics 2 h before the pulse reduced the proportion of bidirectional units observed from 0.98 to 0.70. Antibiotic treatment for 2 h also decreased initiation synchrony in that the proportion of multiunit autoradiograms on which neighboring units showed similar replication patterns (indicating temporally coordinated initiation) was reduced by one-half. These observations indicate that inhibition of protein synthesis alters the normal pattern of DNA initiation.     

CELL ARREST IN Gl AND G2 OF THE MITOTIC CYCLE OF VICIA FABA ROOT MERISTEMS

Experiments were performed with cultured excised primary root tips of Vicia faba ‘Longpod’ to determine: (1) the proportion of meristematic cells arrested in Gl and in G2 during carbohydrate starvation, and to determine if the proportion is fixed or can be varied experimentally; (2) the effect of increased starvation on the ability of arrested cells in Gl and G2 to initiate DNA synthesis and mitosis, respectively, when exogenous sucrose was supplied; and (3) whether puromycin, cycloheximide, or actinomycin D prevented the initiation of DNA synthesis and the onset of mitosis. Microspectrophotometry of nuclear DNA and autoradiographic measurements of incorporated ³H-thymidine showed that 72 hr of starvation immediately after excision produced tissue with more than 70 % of the cells arrested in G2 and less than 30 % in Gl. If cultured for three days and then starved for 72 hr, the tissue had nearly equal numbers of cells arrested in Gl and G2. As the duration of starvation increased, the time required to initiate DNA synthesis and to divide when carbohydrate was replenished also increased. Inhibition of protein synthesis by puromycin and cycloheximide prevented the initiation of DNA synthesis and mitosis, but actinomycin D, an inhibitor of RNA synthesis, did not prevent division of cells from G2 nor DNA synthesis by cells from Gl. The experiments demonstrated that the mitotic cycle of Vicia has two major controls, one in Gl and another in G2, and that other factors determine how many cells are affected by either of these cycle controls.