Protein synthesis and the presence of absence of a measurable G1 in cultured Chinese hamster cells

Antroquinonol displays anticancer potential against human hepatocellular carcinoma cells: a crucial role of AMPK and mTOR pathways

5'AMP-activated protein kinase (AMPK) and the mammalian target of rapamycin (mTOR) are two serine/threonine protein kinases responsible for cellular energy homeostasis and translational control, respectively. Evidence suggests that these two kniases are potential targets for cancer chemotherapy against hepatocellular carcinoma (HCC). Antroquinonol that is isolated from Antrodia camphorate, a well-known Traditional Chinese Medicine for treatment of liver diseases, displayed effective anticancer activity against both HBV DNA-positive and -negative HCC cell lines. The rank order of potency against HCCs is HepG2>HepG2.2.15>Mahlavu>PLC/PRF/5>SK-Hep1>Hep3B. Antroquinonol completely abolished cell-cycle progression released from double-thymidine-block synchronization and caused a subsequent apoptosis. The data were supported by down-regulation and reduced nuclear translocation of G1-regulator proteins, including cyclin D1, cyclin E, Cdk4 and Cdk2. Further analysis showed that the mRNA expressions of the G1-regulator proteins were not modified by antroquinonol, indicating an inhibition of translational but not transcriptional levels. Antroquinonol induced the assembly of tuberous sclerosis complex (TSC)-1/TSC2, leading to the blockade of cellular protein synthesis through inhibition of protein phosphorylation including mTOR (Ser(2448)), p70(S6K) (Thr(421)/Ser(424) and Thr(389)) and 4E-BP1 (Thr(37)/Thr(46) and Thr(70)). Furthermore, the AMPK activity was elevated by antroquinonol. Compound C, a selective AMPK inhibitor, significantly reversed antroquinonol-mediated effects suggesting the crucial role of AMPK. Besides, the loss of mitochondrial membrane potential and depletion of mitochondrial content indicated the mitochondrial stress caused by antroquinonol. In summary, the data suggest that antroquinonol displays anticancer activity against HCCs through AMPK activation and inhibition of mTOR translational pathway, leading to G1 arrest of the cell-cycle and subsequent cell apoptosis.

Central roles of Mg2+ and MgATP2- in the regulation of protein synthesis and cell proliferation: significance for neoplastic transformation

Growth factors are polypeptides that combine with specific membrane receptors on animal cells to stimulate proliferation, but they also stimulate glucose transport, uridine phosphorylation, intermediary metabolism, protein synthesis, and other processes of the coordinate response. There are a variety of nonspecific surface action treatments which stimulate the same set of reactions as the growth factors do, of which protein synthesis is most directly related to the onset of DNA synthesis. Mg(2+) is required for a very wide range of cellular reactions, including all phosphoryl transfers, and its deprivation inhibits all components of the coordinate response that have so far been tested. Growth factors raise the level of free Mg(2+) closer to the optimum for the initiation of protein synthesis. The resulting increase in protein synthesis accelerates progression through G1 to the onset of DNA synthesis and mitosis. None of the other 3 major cellular cations are similarly involved in growth regulation, although internal pH may play an auxiliary role. Almost 10(5) externally bound divalent cations are displaced from membranes for every attached insulin molecule, implying a conformational membrane change that releases enough Mg(2+) from the internal surface of the plasma membrane to account for the increase in free cytosolic Mg(2+). It is proposed that mTOR, the central control point for protein synthesis of the PI 3-K kinase cascade stimulated by insulin, is regulated by MgATP(2-) which varies directly with cytosolic Mg(2+). Other elements of the coordinate response to growth factors such as the increased transport of glucose and phosphorylation of uridine are also dependent upon an increase of Mg(2+). Deprivation of Mg(2+) in neoplastically transformed cultures normalizes their appearance and growth behavior and raises their abnormally low Ca(2+) concentration. Tight packing of the transformed cells at very high saturation density confers the same normalizing effects, which are retained for a few days after subculture at low density. The results suggest that the activity of Mg(2+) within the cell is a central regulator of normal cell growth, and the loss of its membrane-mediated control can account for the neoplastic phenotype.

How cells coordinate growth and division

Size is a fundamental attribute impacting cellular design, fitness, and function. Size homeostasis requires a doubling of cell mass with each division. In yeast, division is delayed until a critical size has been achieved. In metazoans, cell cycles can be actively coupled to growth, but in certain cell types extracellular signals may independently induce growth and division. Despite a long history of study, the fascinating mechanisms that control cell size have resisted molecular genetic insight. Recently, genetic screens in Drosophila and functional genomics approaches in yeast have macheted into the thicket of cell size control.

Platelet-derived growth factor stimulates phosphorylation of the 25 kDa mRNA cap binding protein (eIF-4E) in human lung fibroblasts

Platelet-derived growth factor exerts rapid effects on protein synthesis and polysome formation in cultured cells. We report that platelet-derived growth factor stimulates a rapid phosphorylation of eIF-4E in WI-38 human lung fibroblasts. The effect was dependent on both time and PDGF concentrations. Phosphoserine was the sole phosphoamino acid identified and tryptic phosphopeptide maps showed a single phosphopeptide under both control and PDGF conditions. Phosphorylation of eIF-4E may be of the events required for initiating entry into G1 and commitment into S phase of the cell cycle.

The G1 interval in the mammalian cell cycle: dual control by mass accumulation and stage-specific activities

The temporal determinants of the G1 cell cycle interval were investigated using nine mammalian cell lines. In each case, cells were allowed to proliferate for many cell cycles under conditions that slowed progress through S phase without an equivalent impairment of overall mass accumulation. This disproportionate inhibition of progress through the cell cycle caused newly produced cells to be more massive than usual. Under these growth conditions, the determinants of the length of the G1 interval became evident. For two cell lines, HeLa S3 and NIH 3T3, a protracted S phase, and the resultant increase in mass, resulted in a dramatically shortened G1 interval. Thus, for these cell lines, a major portion of G1 time exists to accommodate mass accumulation needed to initiate the subsequent S phase. Nevertheless, under conditions that protracted S phase and shortened the G1 interval, cells still exhibited a measurable G1 time, reflecting the stage-specific activities within G1. One activity that may be responsible for this obligatory G1 time is the synthesis of a labile protein. For other cells studied here, protraction of S phase also caused proliferating cells to become more massive, but in these cases there was no diminution of the G1 time. For these cells, the entire G1 interval must accommodate G1-specific activities necessary to initiate a new cell cycle. A unifying view of the G1 interval recognizes the two distinct influences that determine the time spent in G1: the need to accumulate sufficient mass to initiate a new DNA-division sequence; and the stage-specific events necessary for the subsequent S phase. The length of the G1 interval is dictated by the longer of these two time-consuming activities.

Cell size of proliferating plant cells increases with temperature: implications in the control of cell division

As chemical reactions related to the regulation of cell proliferation are governed by availability, amount, and concentration of relevant molecules, it has been suggested that cell size is an important factor in the control of cell cycle. We have measured the size of proliferating cells of Allium cepa roots in which growth rate was modified by changes in growth temperature. Two independent cell size parameters have been measured by cytophotometry: cell surface area projection and cell protein content. Average cell sizes of both the proliferating cell population and the subpopulation at the end of mitosis show that cell size increases with growth rate. Calculation of cell size at initiation of DNA replication clearly indicates that average cell size at this point is not growth invariant but positively correlated with growth rate.

Variability of ecdysteroid-induced cell cycle alterations in Drosophila Kc sublines

The cell cycle of two lines isolated from Drosophila Kc cells was followed by flow cytofluorometry and cell counting. The first line is the 8-9K clone which grew in a medium supplemented with 5% serum; the second, named subline KcO, grew in a serum-free medium. The stationary phase is characterized by a G2 cell accumulation: 73% in the 8-9K clone and 50% in the KcO subline. When the medium was supplemented with the steroid moulting hormone 20-hydroxyecdysone, more than 90% of 8-9K cells and 65% of KcO cells were progressively arrested in G2. In the continuous presence of 20-hydroxyecdysone, most of the 8-9K cells remain G2-arrested; no massive G2 release into M was observed and only a few cells were able to divide. When treated for only 3 or 7 days, a transient release into M and proliferation occurred after hormone-free medium renewal, largely masked by G2 cell death. These results are discussed in comparison with other reports on cell cycle alteration induced by ecdysteroids.

Mechanism for differential sensitivity of the chromosome and growth cycles of mammalian cells to the rate of protein synthesis

It has been documented widely that when the generation times of eucaryotic cells are lengthened by slowing the rate of protein synthesis, the duration of the chromosome cycle (S, G2, and M phases) remains relatively invariant. Paradoxically, when the growth of exponentially growing cultures of CHO cells is partially inhibited with inhibitors of protein synthesis, the immediate effect is a proportionate reduction in the rate of total protein, histone protein, and DNA synthesis. However, on further investigation it was found that over the next 2 h the rates of histone protein and DNA synthesis recover, in some cases completely to the uninhibited rate, while the synthesis rates of other proteins do not recover. We called this process chromosome cycle compensation. The amount of compensation seen in CHO cell cultures can account quantitatively for the relative invariance in the length of the chromosome cycle (S, G2, and M phases) reported for these cells. The mechanism for this compensation involves a specific increase in the levels of histone mRNAs. An invariant chromosome cycle coupled with a lengthening growth cycle must result in a disproportionate lengthening of the G1 phase. Thus, these results suggest that chromosome cycle invariance may be due more to specific cellular compensation mechanisms rather than to the more usual interpretation involving a rate-limiting step for cell cycle progression in the G1 phase.

Effects of increased cell mass and altered gene dosage on the timing of initiation of macronuclear DNA synthesis in Paramecium tetraurelia. Implications for cell cycle regulation

In Paramecium, cell mass and macronuclear DNA content can vary substantially, and both variables affect the timing of initiation of macronuclear DNA synthesis. Cells normally begin macronuclear DNA synthesis at 0.25 in the cell cycle when the mean cell mass is about 119% of the initial value. Gene mutations were used to alter cell size by temporarily blocking cell cycle progression and to change DNA content by altering the segregation pattern of macronuclear material to daughter nuclei at fission. Changes in cell mass or macronuclear DNA content imposed at fission or in the subsequent G1 interval do not affect the timing of initiation of DNA synthesis in that cell cycle, but do affect the timing of initiation of DNA synthesis in the subsequent cell cycle. The progeny of cells with lower than average macronuclear DNA content tend to initiate DNA synthesis earlier than other cells. The G1 interval is proportionally shortened when initial cell mass is greater than normal, and no measurable G1 interval is present when initial cell mass equals or exceeds the normal cell mass present at initiation of DNA synthesis. These results suggest that the timing of initiation of DNA synthesis is established during the preceding cell cycle and that the 'timer' mechanism is not significantly affected by either drastic changes in gene dosage or gene concentration during the G1 interval.

Cell cycle controls in higher eukaryotic cells: resting state or a prolonged G1 period?

We express the viewpoint that control over cell growth in higher eukaryotes is achieved predominantly by regular transition of cells from proliferation to rest and vice versa as a result of coordinated interrelationship between intracellular growth inhibitors and extracellular growth factors. The resting state is considered as a special physiological state of a cell where the prereplicative reactions necessary for the onset of DNA synthesis are inhibited. Cells pass into a resting state at each successive cell cycle, with regard to the next cycle, once the threshold level of growth inhibitors has been attained. Cellular rest may thus initiate and proceed in parallel with conventional periods of the cell cycle but in a hidden way. Its termination strictly depends on the appropriate concentration of extracellular growth factors. In the absence of growth factors cells, after completing mitosis, pass into an overt state of rest metabolically different from any period of the cell cycle including G1.

Intracellular pH controls growth factor-induced ribosomal protein S6 phosphorylation and protein synthesis in the G0----G1 transition of fibroblasts

Mitogen-induced intracellular alkalinization mediated by activation of a Na+/H+ antiporter is a common feature of eukaryotic cells stimulated to divide. A Chinese hamster fibroblast mutant (PS120) lacking Na+/H+ antiport activity (Pouysségur et al., Proc natl acad sci US 81 (1984) 4833) [42] possesses an intracellular pH (pHi) 0.2-0.3 units lower than the wild type (CCL39) and requires a more alkaline pHout (pHo) for growth. Here, we show that serum-stimulated ribosomal protein S6 phosphorylation, protein synthesis activation and DNA synthesis re-initiation are pH-regulated events that display a similar threshold pHo value (6.60) in CCL39 cells. pH-Dependencies for initiation of all three events are shifted toward higher pHo values in the mutant PS120, indicating that growth factor-induced alkalinization has a permissive effect on the pleiotypic response. However, cytoplasmic alkalinization per se is insufficient to trigger S6 phosphorylation, polysome formation, and subsequent DNA synthesis. Transient exposure to a non-permissive pHo (6.5) inhibits both the rate of leucine incorporation into proteins and the progression through the G1 phase of the cell cycle. In contrast, cells committed to DNA synthesis are unaltered by the acidic pHo. These observations suggest that pHi by controlling the rate of protein synthesis play a determinant role in the control of cell division.

Histones and their modifications

Histones constitute the protein core around which DNA is coiled to form the basic structural unit of the chromosome known as the nucleosome. Because of the large amount of new histone needed during chromosome replication, the synthesis of histone and DNA is regulated in a complex manner. During RNA transcription and DNA replication, the basic nucleosomal structure as well as interactions between nucleosomes must be greatly altered to allow access to the appropriate enzymes and factors. The presence of extensive and varied post-translational modifications to the otherwise highly conserved histone primary sequences provides obvious opportunities for such structural alterations, but despite concentrated and sustained effort, causal connections between histone modifications and nucleosomal functions are not yet elucidated.

Mechanism for differential sensitivity of the chromosome and growth cycles of mammalian cells to the rate of protein synthesis

It has been documented widely that when the generation times of eucaryotic cells are lengthened by slowing the rate of protein synthesis, the duration of the chromosome cycle (S, G2, and M phases) remains relatively invariant. Paradoxically, when the growth of exponentially growing cultures of CHO cells is partially inhibited with inhibitors of protein synthesis, the immediate effect is a proportionate reduction in the rate of total protein, histone protein, and DNA synthesis. However, on further investigation it was found that over the next 2 h the rates of histone protein and DNA synthesis recover, in some cases completely to the uninhibited rate, while the synthesis rates of other proteins do not recover. We called this process chromosome cycle compensation. The amount of compensation seen in CHO cell cultures can account quantitatively for the relative invariance in the length of the chromosome cycle (S, G2, and M phases) reported for these cells. The mechanism for this compensation involves a specific increase in the levels of histone mRNAs. An invariant chromosome cycle coupled with a lengthening growth cycle must result in a disproportionate lengthening of the G1 phase. Thus, these results suggest that chromosome cycle invariance may be due more to specific cellular compensation mechanisms rather than to the more usual interpretation involving a rate-limiting step for cell cycle progression in the G1 phase.

Presence or absence of a G1 period in the cell cycle and growth control in a Chinese hamster cell line

Cells of the V79-8 line grow with little or no G1 period. Serum or isoleucine deprivation results in cell death rather than entry into quiescence. Introduction of a G1 period of 4-5 h by treatment with a mutagen is not sufficient to re-establish the ability to enter quiescence. The experiments described here show that introducing a G1 period by mutation that lowers the rate of protein synthesis does not restore to the cell any competence to arrest in G1 and enter a state of quiescence.

Density-dependent regulation of growth in somatic hybrids between normal Chinese hamster fibroblasts and V79-8 (G1-) cells

The purpose of this work was to determine the relationship between the presence of a G1 period in the mitotic cycle and a cell's ability to respond to density-dependent regulation of growth (DDR). Somatic hybrids were obtained between normal fibroblasts from newborn Chinese hamsters, which show a strong response to DDR, and V79-8 Chinese hamster cells, which are insensitive to DDR. Two variant V79-8 sublines were used, one reported to lack a G1 period (G1-) and the other with a G1 period (G1+). Fourteen hybrid clones were isolated in selective medium and analysed for growth properties and cell cycle parameters; their hybrid nature was supported by chromosome counts. All hybrid clones, irrespective of whether a V79-8 G1- or G1+ cell was one of the parents, showed pronounced DDR and had G1 periods of various lengths. Previous experiments had shown the absence of G1 to be dominant in somatic hybrids between V79-8 G1- and G1+ cell lines. Our results may mean that the G1- property provided by V79-8 is unable to overcome the very long G1 of normal fibroblasts, or in cells that can be arrested in G1 in response to DDR, some function prevents the dominant effect of the G1- cell on at least part of the G1 period.

Control in previous and present generations of preparation for entry into S phase and the relationship to resting state in 3Y1 rat fibroblastic cells

In both the presence and absence of serum, 3Y1 rat fibroblastic cells synchronized at early S phase by aphidicolin entered M phase 6 h after removal of aphidicolin. However, in the second generation their entry into S phase in the presence of serum was delayed due to the deprivation of serum in the first generation. A similar delaying effect in the second generation was observed when the resting cells were stimulated by serum and then deprived of serum during a period of 8 h preceding mitosis. In both cases, the interval between mitosis and entry into S phase in the second generation was almost equal to that required for the resting cells to enter S phase when stimulated by serum. A similar delaying effect was also observed when the cells, synchronized at early S phase, were kept in suspension culture in the presence of serum for a period in the first generation. Results of a similar type of experiments using various combinations of growth factors showed that, when the G1 period in the second generation was shortened by exposure to growth factors in the first generation, and when the resting cells were stimulated to enter S phase, the same combination of growth factors was required. These and previous results suggest that the preparation for entry into S phase is controlled in both previous and present generations of 3Y1 cells.

Independent regulation by sodium butyrate of gonadotropin alpha gene expression and cell cycle progression in HeLa cells

Sodium butyrate alters the growth and gene expression of a variety of differentiating and neoplastic cell types. For example, addition of 5 mM butyrate to HeLa cells is reported to both induce gonadotropin alpha subunit biosynthesis and block cell cycling in G1. We have studied these two actions of butyrate on HeLa cells and found that they are regulated in distinct ways. The induction of alpha subunit synthesis was due to an increase in the rate of transcription of the alpha gene. Using synchronized populations of HeLa cells, we determined that butyrate stimulates alpha transcription throughout the cell cycle. In contrast, treated cells arrest in G1 only if exposed to butyrate for a discrete period during the previous S phase. We conclude that butyrate inhibits DNA synthesis through a cell cycle-specific action that is independent from its direct action to stimulate transcription of the gonadotropin alpha gene.

Independent regulation by sodium butyrate of gonadotropin alpha gene expression and cell cycle progression in HeLa cells

Sodium butyrate alters the growth and gene expression of a variety of differentiating and neoplastic cell types. For example, addition of 5 mM butyrate to HeLa cells is reported to both induce gonadotropin alpha subunit biosynthesis and block cell cycling in G1. We have studied these two actions of butyrate on HeLa cells and found that they are regulated in distinct ways. The induction of alpha subunit synthesis was due to an increase in the rate of transcription of the alpha gene. Using synchronized populations of HeLa cells, we determined that butyrate stimulates alpha transcription throughout the cell cycle. In contrast, treated cells arrest in G1 only if exposed to butyrate for a discrete period during the previous S phase. We conclude that butyrate inhibits DNA synthesis through a cell cycle-specific action that is independent from its direct action to stimulate transcription of the gonadotropin alpha gene.

The role of the G1 period in the life cycle of eukaryotic cells

The objective of this study was to test the concept that the G1 period lacks any specific function in the life cycle of mammalian cells and hence could be drastically reduced without any effect on the generation time. HeLa cells were grown in medium containing an optimum dose (60 microM) of hydroxyurea at which the duration of S period was prolonged with little or no increase in generation time. At this concentration of hydroxyurea, we observed a maximum of 3 h (or 28.5%) reduction in the G1 period. We also studied the effects of synchronization in S phase by single and double thymidine blocks on cell size and its relationship to the duration of G1 in the subsequent cycle. By these treatments, we could reduce the G1 period by not more than 2 to 3 h. The reduction in G1 period was not directly proportional to the size (volume) of the G1 cells. These results suggest that G1 period has certain specific functions and cannot be eliminated by alterations in culture conditions.

Decreased protein-synthetic activity is an early consequence of spermidine depletion in rat hepatoma tissue-culture cells

Hepatoma tissue-culture (HTC) cells were exposed to DL-alpha-difluoromethylornithine (DFMeOrn), a specific irreversible inhibitor of ornithine decarboxylase. Concomitantly with the decrease in spermidine, a decrease in the amount of ribosomes in polyribosomes was observed. Spermine concentrations remained essentially comparable with those in cells not exposed to this inhibitor. Exposure of putrescine- and spermidine-depleted HTC cells to spermidine or spermine rapidly reversed the effect of DFMeOrn on polyribosome profiles, whereas addition of putrescine to the cell culture medium had an effect only after its transformation into spermidine and spermine. The results show that the perturbation of polyribosome formation in DFMeOrn-treated HTC cells is due to spermidine deficiency and that a normal polyamine complement is required for optimal protein-synthetic activity in these cells. The results also indicate that protein synthesis is perturbed before DNA synthesis during depletion of putrescine and spermidine in HTC cells.

Growth and the cell cycle of the yeast Saccharomyces cerevisiae. II. Relief of cell-cycle constraints allows accelerated cell divisions

For cells of the yeast Saccharomyces cerevisiae, conditions which limit S phase or nuclear division allow steady-state division kinetics without significant effects on growth. Such cells become unusually large. When large proliferating cells were released from any one of several conditions which slowed progress through the DNA-division sequence, they underwent a period of accelerated division with a cell cycle devoid of a G1 interval, as evidenced by low proportions of unbudded cells and shifted execution points for the 'start' cell cycle step. We interpret these results to mean that when released from conditions slowing the DNA-division sequence these large cells continue for several cell doublings to accumulate mass fast enough to eliminate the need for a G1 interval. The results support the conclusion that the yeast G1 interval is the for most part only an interval of growth.

Partial elimination of G1 and G2 periods in higher plant cells by increasing the S period

Meristematic cells from Allium cepa L roots can attain a steady-state of growth at both 15 and 25 degrees C in the presence of drugs, hydroxyurea and 5-amino-uracil, which reduce the rate of DNA synthesis. These drugs, at used concentrations, significantly lengthen the S period without altering the cell growth rate, as indicated by the maintenance of the generation time. It has been observed that steady-state populations respond to a gradual increase in S by a reduction of G2 until a minimum value; with larger lengthening of S, both G1 and G2 are reduced. Natural synchronous populations have been used to study cell cycle parameters during transition from the physiological steady-state to the new one created by the presence of the drug. G2 (but not G1) is reduced during transition even in the presence of maximum drug concentrations that do not alter the cell growth rate. Both the S period and the division time are lengthened during transition. These observations support the concept that certain fractions of G1 and G2 are expendable, because they have no role in the DNA-division sequence of cell cycle events. We conclude that cell size regulates the length of these fractions by means of a negative correlation.

The G1 distribution of "G1-less" V79 Chinese hamster cells

The V79-8 line of Chinese hamster cells has been reported to lack a measurable G1 phase. However, using a combination of time-lapse cinemicroscopy and [3H]thymidine autoradiography, we have found these cells to have a median G1 duration ranging from 1.4 to 2.6 h in different experiments, accounting for more than 15% of the median cycle time. The youngest cell labelled (in seven experiments) was 0.73 h old at the time of fixation suggesting a minimum G1 of between 0.40 and 0.73 h (the duration of the [3H]thymidine pulse being 0.33 h). In those experiments where steady-state proliferation could be established unequivocally, variability in G1 times accounted for all of the variability in cycle times. In addition, the distribution of G1 times (and cycle times) was well described by the two-transition version of the transition probability model. Nevertheless, changes in the average duration of G1 (and hence changes in the transition probabilities) played a comparatively minor role in determining proliferation rate. Instead, the length of S + G2 was markedly influenced by the composition of the culture medium. For purposes of comparison with the 'G1-less' V79-8 line, we have also examined a revertant derived from it (G1+5c) reported to have regained a substantial G1 phase. We are able to confirm that its G1 is indeed longer, the youngest labelled cell being 2.48 h old at the time of fixation. Unlike the parent line, there appeared to be more variability in G1 times than could be explained by two random transitions alone. The proliferation rate of the G1+5c revertant was unusually sensitive to the composition of the culture medium, suggesting the possibility of a metabolic defect.

Enhanced synthesis and stabilization of Mr 68,000 protein in transformed BALB/c-3T3 cells: candidate for restriction point control of cell growth

We have proposed that transformation of cells to tumorigenicity by chemical carcinogens can depend upon stabilization of a protein responsible for growth regulation. Cell kinetic experiments in which normal and benzo[a]pyrene-transformed BALB/c-3T3 cells were pulsed with cycloheximide indicated this protein should have a half-life of a few hours in normal cells and be considerably more stable in transformed cells [Campisi, J., Medrano, E. E., Morreo, G. & Pardee, A. B. (1982) Proc. Natl. Acad. Sci. USA 79, 436-440]. A protein with these properties has not yet been reported. We have searched for such a protein using two-dimensional electrophoresis to resolve protein from cells labeled with [35S]methionine. Among approximately 1,000 proteins that were resolved in these gels, we have found one that has a greater rate of synthesis and stability in benzo[a]pyrene-transformed than in untransformed cells. This result satisfies a necessary prediction of our labile protein hypothesis. We suggest that this protein could be important in determining the loss of growth regulation in these tumor cells.

Effects of retinoic acid on protein synthesis in cultured melanoma cells

Retinoic acid reduces the growth rate of mouse S91 melanoma cells in culture and increases the proportion of cells in the G1 phase of the cell cycle. Because of the integral role protein synthesis has been shown to play in growth control we studied the effect of retinoic acid on the protein synthesis machinery with a cell-free system developed from the melanoma cells. This system was capable of translating endogenous mRNA, exogenous globin mRNA, and the synthetic template poly(U). Of the above activities of the protein synthesis system only the translation of endogenous mRNA was reduced significantly in the cell-free system prepared from retinoic acid-treated cells. Analyses of the amount and function of RNA revealed that treatment with retinoic acid leads to reductions in total RNA content, in the proportion of ribosomes in polysomes, in the amount of poly(A)RNA, and in the amount of polysome-associated mRNA. All these effects of retinoic acid contribute to the decrease in protein synthesis activity of treated cells. Two-dimensional electrophoresis analysis of L-[35S]methionine-labeled proteins produced by untreated and treated cells revealed only a few quantitative differences. We suggest that retinoic acid-induced suppression of protein synthesis activity may be the cause for growth inhibition.

Effects of serum deprivation on the initiation of DNA synthesis in the second generation in rat 3Y1 cells

Rat 3Y1 cells arrested at early S by hydroxyurea traversed the remainder of S and G2 and completed mitosis after removal of the drug, irrespective of the absence of serum from the culture medium. When cells were deprived of serum for a period between early S and mitosis after removal of hydroxyurea, the cells delayed entry into S in the presence of serum in the second generation for the time length approximately equal to that of serum deprivation. When mitotic cells, which had been continuously exposed to serum after removal of hydroxyurea, were deprived of serum for the next 24 hours and then were reexposed to serum, the cells delayed entry into S for more than 24 hours (more than the time length of serum deprivation). On the other hand, the cells already deprived of serum between early S and G2 in the first generation were less delayed in entry into S after postmitotic 24-hour serum deprivation than were the cells exposed to serum between early S and G2 in the first generation. These results suggest that serum-dependent events continue to occur in the first generation for on-time entry into S in the next generation, and that these premitotic events (the potential for entry into S) decay if serum is absent for a long period of time after mitosis.

Restriction point control of cell growth by a labile protein: evidence for increased stability in transformed cells

It has been proposed that animal cells must accumulate a labile protein(s) before they can pass the restriction (R) point in the G1 phase of the cell cycle [Rossow, P. W., Riddle, V. G. H. & Pardee, A. B. (1979) Proc. Natl. Acad. Sci. USA 76, 4446--4450]. Here, we present evidence that this R protein acquires increased stability in transformed 3T3 cells, thereby allowing these cells to continue growth under conditions that arrest untransformed cells. Low doses of cycloheximide or histidinol drastically reduced the rate at which normal 3T3 (A31) fibroblasts in early G1 could enter DNA synthesis. These drugs had less effect on entry of two tumorigenic A31 derivatives, BPA31 and SVA31, in S, although measurement of [3H]leucine incorporation showed that the inhibitors were equally effective in the three cell lines. The hypothesis is that the transformed lines are less sensitive because moderate inhibition of their R protein synthesis is compensated by lower rates of protein degradation. To test this idea, we completely inhibited cytoplasmic protein synthesis for several hours shortly before A31 and BPA31 cells had reached the R point. After removal of inhibitor, A31 cells showed delays in the onset of S that were in excess of the inhibitor pulse, consistent with decay of labile protein during the pulse. BPA31 cells showed no excess delays, suggesting a much more stable R protein. The half-life of the R protein was estimated as 2.5 hr in A31 cells, indicating that, in these cells, R protein synthesis starts at the beginning of G1. In the BPA31 cells the R protein showed no signs of decay for at least 8 hr.

Post-transcriptional control of protein synthesis in Balb/c-3T3 cells by platelet-derived growth factor and platelet-poor plasma

Platelet-derived growth factor (PDGF) and platelet-poor plasma, which lacks PDGF, both induce a rapid increase in the rate of total protein synthesis within quiescent, density-arrested Balb/c-3T3 cells. This stimulation of protein synthesis is associated with an increased aggregation of ribosomes into polyribosomes. Nuclear functions are not required for this response, as demonstrated by the observation that this stimulation of protein synthesis occurs in cells pretreated with actinomycin D and in enucleated cells (cytoplasts). The response to PDGF persists even after PDGF has been removed from the culture medium, but in contrast, when plasma is removed from the medium, polysomes disaggregate and protein synthesis declines. PDGF and plasma do not function synergistically to increase protein synthesis, whereas they do to induce optimum DNA synthesis. Thus stimulation of the translational apparatus may be necessary for the mitogenic response of Balb/c-3T3 cells to growth factors, but it is not by itself sufficient.

The role of protein accumulation in the cell cycle control of human NHIK 3025 cells

The cell cycle kinetics of NHIK 3025 cells, synchronized by mitotic selection, was studied in the presence of cycloheximide at concentrations (0.125-1.25 microM) which inhibited protein synthesis partially and slowed down the rate of cell cycle traverse. The median cell cycle duration was equal to the protein doubling time in both the control cells and in the cycloheximide-treated cultures at all drug concentrations. This conclusion was valid whether protein synthesis was continuously depressed by cycloheximide throughout the entire cell cycle, or temporarily inhibited during shorter periods at various stages of the cell cycle. These results may indicate that cell division does not take place before the cell has reached a critical size, or has completed a protein accumulation-dependent sequence of events. When present throughout the cell cycle, cycloheximide increased the median G1 duration proportionally to the total cell cycle prolongation. However, the entry of cells into S, once initiated, proceeded at an almost unaffected rate even at cycloheximide concentrations which reduced the rate of protein synthesis 50%. The onset of DNA synthesis seemed to take place in the cycloheximide-treated cells at a time when the protein content was lower than in the control cells. This might suggest that DNA synthesis in NHIK 3025 cells is not initiated at a critical cell mass.

Most of the G1 period in hamster cells is eliminated by lengthening the S period

Two Chinese hamster cell lines, G1+-1 and CHO, have been grown in the presence of low concentrations of hydroxyurea to determine how a slowing DNA synthesis (i.e., a lengthening of the S period) affects the length of the G1 period. Hydroxyurea concentrations of approximately 10 microM do not alter the generation times of these cell lines but do cause increases in S with corresponding decreases in G1. In both cell lines, 10 microM hydroxyurea reduces G1 to an absolute value of 1 hr, which represents decreases of 70% (G1+-1) and 60% (CHO) from control values. Higher concentrations of hydroxyurea increase the generation times and lengths of S for both cell lines but do not reduce G1 below the minimum value of 1 hr. These observations indicate that the majority of G1 is expendable and most of G1 therefore cannot contain specific events required for the initiation of DNA synthesis. This result supports the hypothesis that G1 is a portion of the cell growth cycle but not of the chromosome cycle.

Nature of the G1 phase of the yeast Saccharomyces cerevisiae

Under conditions that protract the S phase for Saccharomyces cerevisiae without affecting steady-state rates of cell growth or proliferation, there were striking decreases in the length of the G1 period. These decreases were localized in the period between mitosis and the start event that initiates a new cell cycle. We conclude that this major fraction of the G1 period has no functional role in the DNA-division sequence of cell cycle events.