DNA synthesis and mitotic activity in cells of regenerating rat liver following x-irradiation in stages GO and Gl]

Effect of X-rays on DNA synthesis and mitotic activity of regenerating liver cells has been studied. The irradiation was performed at a dose of 630 rad before hepatectomy and 2.5 and 6 hours after the stimulation of liver. With the stimulated liver being irradiated, the number of cells synthetizing DNA and entering into mitosis was seen reduced almost twice, whereas DNA synthesis and entering into mitosis were delayed, resp., by 4 and 6 hours. Irradiation of liver before the stimulation brings about a delay in DNA synthesis and in start of mitosis by 2 and 4 hours, resp., without reducing the numbers of cells capable to synthesize DNA and to enter mitosis.     

Cycle reset in a melanoma cell line caused by cooling

When cells in culture are released from G0 into cycle by diluting into fresh medium there is a delay of many hours before they re-enter the cycle and start DNA synthesis. A mouse melanoma cell line designated HP2 has been used to investigate the effects of non-standard temperatures between the time of plating and DNA synthesis. When the cells were incubated in a 5% CO2 box at 8 degrees C for periods during the G0-G1 transition there was an extra delay before the start of S, approximately equal to the time that the cells were held at 8 degrees C and independent of the time when the cold pulse was administered. When the cells were cooled to 25 degrees C the delay was longer than the time for which the cells had been kept at 25 degrees C, and this extra delay was also dependent on the point in G0-G1 when the cells were cooled, as though the cells could be reset to an earlier time by this treatment. It is suggested that a labile substance required for progression is destroyed faster than it is made at 25 degrees C but at 8 degrees C the rate of destruction is very low. Another phenomenon noted during these cooling experiments was that the peak height of the S phase profile, as measured by frequent pulse-thymidine incorporation experiments, was substantially higher for cells which had been cooled at a later stage in the G0-G1 transition, even though the overall times at 37 degrees C and at the colder temperature were identical. By varying the temperature of the cold pulse it was possible to separate the change in the peak height and the delay as separate entities.     

Induction of hyaluronic acid synthetase activity in rat fibroblasts by medium change of confluent cultures

Hyaluronic acid synthesis in cultured cells usually occurs during the growth phase. The relation between hyaluronic acid synthetase activity and cell proliferation is studied. The synthetase activity in rat fibroblasts is high during the growth phase, but low in the stationary phase. When the old medium of stationary cultures is renewed with fresh medium containing 20% calf serum, DNA synthesis occurs synchronously between 12 and 20 hours, followed by cell division. Under these conditions, the hyaluronic acid synthetase activity is significantly induced within two hours, reaching a maximum level at 5–8 hours, and then decreases gradually. This induction of the synthetase, which shows a high turnover rate, requires continued synthesis of both RNA and protein. Furthermore, the induction of both DNA and hyaluronic acid synthesis is found to be caused by calf serum added in the medium. However, dialysis and ultrafiltration of the serum permit us to concentrate an active fraction with a high molecular weight, which induces the synthetase activity, but not DNA synthesis.     

Reversible alterations in the mitotic cycle of chick embryo cells in various states of growth regulation

Chick embryo cells which have been kept overnight at pH 6.8 in the absence of serum multiply very slowly. Only a small fraction of cells is in the S period at any given time, and the rate of uptake of 2-deoxy-D-glucose is very low. Upon raising the pH to 7.4 and adding serum (“turn-on”) the uptake of 2-deoxy-D-glucose increases immediately; the rate of DNA synthesis increases after a lag of about 4 hours, and represents an increase in the fraction of cells synthesizing DNA. The uptake of 2-deoxy-D-glucose is rapidly returned to its original low rate at any time by again lowering the pH and removing serum (“turn-off”). The synthesis of DNA in the culture remains constant or continues to rise at a markedly reduced rate following the same treatment. Lowering pH or removing serum independently of each other is less efficient at inhibiting the increase in DNA synthesis than the combined treatment but each accomplishes a similar result. Cultures which have been “turnedoff” during the early stages of the rapid increase in DNA synthesis, resume their prior rate of increase immediately if “turned-on” again within 2.5 hours. If the cultures have been “turned-off” for 5.5 hours before restoring the “turn-on,” there is a 2 hour delay before they resume an increased rate of DNA synthesis. The results indicate that chick embryo cells do not become committed to the initiation of DNA synthesis until shortly before, or at the time of the onset of the S period. Up to 96% of the cells in post-confluent cultures growing in conventional medium become labeled upon continuous, prolonged exposure to ³H-thymidine. Seventy-eight percent of the cells in serum-deprived cultures growing at a very low rate become labeled. These and other considerations suggest that the inhibition of cell multiplication by high population density or serum deprivation is caused by a lengthening of the time cells remain in the prereplicative G₁ period rather than by shifting cells into a qualitatively distinct G₀ period. There may, however, be a period common to all cells regardless of growth rate, in which cells are not progressing toward the S period. The length of this variable period would then determine the growth rate of a population of cells.     

Early alterations in amino acid pools and protein synthesis of diploid fibroblasts stimulated to synthesize DNA by addition of serum

Diploid human fibroblasts in culture (WI 38) were allowed to reach a stationary phase and were then stimulated to reenter DNA synthesis and cell division by addition of serum to the culture medium. The rate of protein synthesis increased during the first hours after addition of serum reaching at three hours a plateau value that continued for at least 24 hours after serum addition. Inhibition of protein synthesis during the early hours after serum addition abolished the stimulation of DNA synthesis occurring 20 to 28 hours later. Increased protein synthesis was preceded by a rapid decrease in the intracellular pool size of most amino acids. These changes were independent of concomitant protein synthesis. They suggest that serum exerts an immediate effect on the function of the cell membrane.     

Relationship between cell proliferation, chromatin template activity and accumulation of nuclear proteins

Trypsinization of confluent monolayers of WI-38 cells causes an extensive loss of nuclear proteins. The loss of nuclear proteins is restored only several hours after the cells have been replated at a lower density in 10% serum. When trypsinized fibroblasts are replated at a lower density in 10% serum, there is also a sustained progressive leading to DNA synthesis and cell division. If 0.3% serum is used instead of 10%, there is a modest increase in nuclear template activity, but not accumulation of nuclear proteins and no DNA synthesis or cell division.     

Cycle reset in a melanoma cell line caused by cooling

Abstract When cells in culture are released from G₀ into cycle by diluting into fresh medium there is a delay of many hours before they re-enter the cycle and start DNA synthesis. A mouse melanoma cell line designated HP2 has been used to investigate the effects of non-standard temperatures between the time of plating and DNA synthesis. When the cells were incubated in a 5% CO₂ box at 8^°C for periods during the G₀-G₁ transition there was an extra delay before the start of S, approximately equal to the time that the cells were held at 8^°C and independent of the time when the cold pulse was administered. When the cells were cooled to 25^°C the delay was longer than the time for which the cells had been kept at 25^°C, and this extra delay was also dependent on the point in G₀-G₁ when the cells were cooled, as though the cells could be reset to an earlier time by this treatment. It is suggested that a labile substance required for progression is destroyed faster than it is made at 25^°C but at 8^°C the rate of destruction is very low. Another phenomenon noted during these cooling experiments was that the peak height of the S phase profile, as measured by frequent pulse-thymidine incorporation experiments, was substantially higher for cells which had been cooled at a later stage in the G₀-G₁ transition, even though the overall times at 37^°C and at the colder temperature were identical. By varying the temperature of the cold pulse it was possible to separate the change in the peak height and the delay as separate entities.     

Effects of the tumor promoter TPA on the induction of DNA synthesis in normal and RSV-transformed rat fibroblasts

Induction of DNA synthesis by the tumor promoter tetradecanoyl phorbol acetate (TPA) was studied in a line of cultured rat fibroblasts (Rat-1) and their ffRous sarcoma virus-transformed derivative (Rat-1(RSV)). Following serum deprivation for 54 h to achieve quiescene, semiconservative DNA replication was measured by incubation of cells in BrdUrd and FdUrd after serum stimulation in the presence or absence of TPA. Optimal concentrations of TPA (0.1–0.5 μg/ ml) in serum-free medium induced a small increase (10–15%) in the amount of DNA made over a 30-h period in both Rat-1 and Rat-1 (RSV) cells. When Rat-1 cells were stimulated by a 4-h serum pulse, 30% of the DNA was replicated by 30 h. If the serum pulse was follwed by TPA addition, 702% DNA replication wass observed. If the serum pulse was preceded by TPA addition, the onset of DNA synthesis waas delayed by several hous, but stimulation of DNA synthesis occurred. In contrast, the Rat-1 (RSV) cells did not show an increase in DNA synthesis induced by TPA in similar protocols, but the serum-induced onset on DNA synthesis was delayed by several hours in the presence of TPA. Therefore, TPA acts as a co-inducer of DNA synthesis in the Rat-1 but not in the Rat-(RSV) cells. The parent alcohol, phorbol, was inactive in Rat-1 cells, but delayed the onset of DNA synthesis in the Rat(RSV) cells. We conclude that the co-inducing and delaying activities of TPA on DNA synthesis appear to be distinct and to act at different points in the G₁ phase of the cell cycle.     

THE MECHANISM OF 5-AMINOURACIL-INDUCED SYNCHRONY OF CELL DIVISION IN VI CIA FABA ROOT MERISTEMS

Cessation of mitosis was brought about in Vicia faba roots incubated for 24 hours in the thymine analogue, 5-aminouracil. Recovery of mitotic activity began 8 hours after removal from 5-aminouracil and reached a peak at 15 hours. If colchicine was added 4 hours before the peak of mitoses, up to 80 per cent of all cells accumulated in mitotic division stages. By use of single and double labeling techniques, it was shown that synchrony of cell divisions resulted from depression in the rate of DNA synthesis by 5-aminouracil, which brought about an accumulation of cells in the S phase of the cell cycle. Treatment with 5-aminouracil may have also caused a delay in the rate of exit of cells from the G₂ period. It appeared to have no effect on the duration of the G₁ period. When roots were removed from 5-aminouracil, DNA synthesis resumed in all cells in the S phase. Although thymidine antagonized the effects of 5-aminouracil, an exogenous supply of it was not necessary for the resumption of DNA synthesis, as shown by incorporation studies with tritiated deoxycytidine.     

Differentiation of lymphoid cells. A selective anti-mitogenic component of normal serum which inhibits the induction of immunoglobulin production.

Rabbit lymph node cell populations cultured in vitro in the presence of fetal calf serum are induced to produce immunoglobulin M-secreting cells. The induction of such immunoglobulin production, measured by the capacity of the cell population to secrete immunoglobulins, was inhibited when cells were cultured with sera from a variety of species despite the presence of fetal calf serum. The addition of such inhibitory serum 36 hours after initiation of the cell culture or thereafter was without effect on the extent of induction of immunoglobulin production. On the other hand, the presence of inhibitory serum in culture during only the first 24 hours yielded the same inhibition as when serum was present throughout the 72-hour culture period. Inhibitory sera also suppressed the incorporation of thymidine into DNA. The induction of immunoglobulin production and the incorporation of thymidine into DNA were essentially equally inhibited by the same range of serum concentrations. Unlike conventional inhibitors of DNA synthesis, the inhibitory sera exhibited selective specificity with regard to the kind of cells that could be affected. Thus, such sera inhibited the DNA synthesis of lymph node cells cultured in the presence of fetal calf serum but did not inhibit concanavalin A-stimulated DNA synthesis of such cultured cells and, similarly, serum did not inhibit DNA synthesis of thymus cells cultured in the presence of fetal calf serum. The sera of all species examined were inhibitory except for fetal sera. As judged from a quantitative assay, bovine and porcine serum contained the highest titer of inhibitor, whereas sera from human, rat, mouse, and rabbit were clustered in a group exhibiting less inhibitor. Ascites fluid and lymph node extracellular fluids contained less inhibitor than found in the serum of the same animal and lysates of washed lymph node cells were devoid of inhibitor. Although fetal bovine serum and newborn bovine serum did not contain the inhibitor, it was detectable within 24 hours of parturition. The inhibitor is of relatively large apparent molecular weight (about 300,000) and has been purified about 70-fold.     

Histone acetylation and histone synthesis in mouse fibroblasts during quiescence and restimulation into S-phase

Mouse NIH 3T3 fibroblasts were starved by serum depletion and subsequently restimulated by addition of serum. Histone acetylation and histone synthesis were studied from the beginning of starvation to the point where most of the cells were in S-phase utilizing electrophoretic and fluorographic techniques. We found that the major part of histone acetylation and histone synthesis occurs during S-phase but that also in the absence of DNA synthesis there are significant changes in the acetylation and synthesis rates of the core histones which occur during the first 6 hours of serum stimulation of quiescent cells, and between 24 and 48 hours of serum starvation.     

The different roles of serum and calcium in the control of proliferation of BALB/c 3T3 mouse cells.

Proliferatively inactive BALB/c 3T3 mouse cells in dense cultures initiate a growth-division cycle upon exposure to fresh calf serum in a low-calcium (0.01 mM) medium. If these calcium-deprived cells are not supplied with calcium sometime during the first 10 hours after serum stimulation, they will rapidly return to a proliferatively inactive state without initiating DNA synthesis. The prereplicative development of such stimulated calcium-deprived cells appears to stop at an advanced stage, because addition of calcium as late as 10 hours after serum exposure rapidly initiates DNA synthesis, and enables the culture's DNA-synthetic activity subsequently to reach its peak value at the same time as in control cultures.     

Regulation of thymidine kinase activity in the cell cycle by a labile protein

Previous studies have shown that the onset of DNA synthesis in Balb/c 3T3 cells appears to be regulated by a labile protein. We have found that induction of thymidine kinase (TK) activity, after quiescent cells are stimulated by the addition of serum, is similarly regulated by a labile protein. Eight hours after serum stimulation, a 6-h pulse of cycloheximide (CHM) caused an excess delay of 2 h in TK induction. A similar delay also was found in the induction of thymidylate synthase (TS). In contrast, the benzo(a)pyrene transformed 3T3 cell line, BP-A31, which had previously been shown to have no excess delay for the onset of DNA synthesis also had no excess delay for the induction of TK activity after a pulse of CHM. The induction of TK was inhibited by actinomycin D and dichlororibofuranosylbenzimidizole (DRB) suggesting a requirement for new RNA synthesis. It did not appear to depend on DNA synthesis as it was not blocked by aphidicolin. In conclusion, the induction of TK activity appears to be regulated by the same labile cellular signal as the onset of DNA synthesis, and to depend on an increase in the level of TK mRNA in late G1 or early S phase.     

DNA synthesis and mitosis in a temperature sensitive Chinese hamster cell line

Viability, DNA synthesis and mitosis have been followed in the temperature sensitive Chinese hamster cell mutant K12 under permissive and non-permissive conditions. On incubation at 40°C cells retained their ability to form colonies at 33°C for 15 to 20 hours, but viability was lost gradually during the following 20 hours. When random cultures of K12 were shifted to 40°C the rate of DNA synthesis was normal for three to four hours but then decreased markedly, reaching 95% inhibition after 24 hours. Under the same conditions mitosis was inhibited after 15 hours. If cultures which had been incubated at 40°C for 16 hours were placed at 33°C the rate of DNA synthesis increased five hours after the shift down and mitosis 18 hours after. These results can be interpreted on the assumption that K12 at 40°C is unable to complete a step in the cell cycle which is essential for DNA synthesis and which occurs three to four hours before the start of S at 33°C.     

Stimulation of DNA synthesis in cultures of mouse embryo fibroblast-like cells

Stimulation of the DNA synthesis and mitoses in stationary cultures of mouse embryo fibroblast-like cells was induced by various agents such as ribonuclease, digitonin, fresh medium and commercial preparations of hyaluronidases. Time sequence of stimulation was similar in experiments with all these agents. Cells were activated to enter S phase from GI phase. The rise of the number of DNA-synthesizing cells was preceded by a latent period of about 8–12 hours with the maximal number of DNA-synthesizing cells being observed at 16–24 hours. Mitotic wave was observed after the wave of DNA synthesis. Stimulation of DNA synthesis and mitosis was not preceded by any significant decrease of an average cell density in the culture. The progeny of activated cells had no greater chance than other cells to be activated again when stimulation was repeated. It is concluded that similar proliferative reactions can be induced in stationary cultures by a variety of diverse agents. Possible role of cell surface changes in the induction of these reactions is discussed.     

Inhibition of viral DNA synthesis in stationary chicken embryo fibroblasts infected with avian retroviruses.

Previously, we reported (Fritsch and Temin, J. Virol. 21:119-130, 1977) that infectious viral DNA was not present in spleen necrosis virus-infected stationary chicken cells. However, a stable intermediate was present in such infected stationary cells as evidenced by the appearance of infectious viral DNA shortly after serum stimulation of these cells. After serum stimulation of infected stationary cells, the infectious viral DNA appeared first in the nucleus. In contrast, in infected dividing cells the infectious viral DNA appeared first in the cytoplasm. Significantly reduced amounts of complete plus- or minus-strand viral DNAs were detected by nucleic acid hybridization in stationary chicken cells infected with spleen necrosis virus or Schmidt-Ruppin Rous sarcoma virus compared with the amounts detected in infected dividing cells. These experiments indicated that infected stationary cells did not contain complete noninfectious copies of viral DNA. Furthermore, 5-bromodeoxyuridine labeling and cesium chloride density gradient centrifugation analysis of the infectious viral DNA that appeared after serum stimulation of infected stationary cells indicated that most viral DNA synthesis occurred after addition of fresh serum.     

Shifting in the duplication time of sex chromosomes in the rat

Duplication of sex chromosomes was studied in bone marrow cells from adult rats and in short-term cultures of rat fetus cells. Results obtained indicate that: a) G₂ period takes 4 hours in cells from fetuses and 3 hours in bone marrow cells, b) S period lasts 7 hours in bone marrow cells and about 20 hours in short-term cultured cells from fetuses, c) In cells from female fetuses one X-chromosome is the last to start DNA synthesis and also one of the X's is the last to end replication, d) In cells from female adult rats both X-chromosomes start and finish DNA synthesis early, e) In both line of cells the Y-chromosome was the last to begin and the last to finish DNA synthesis. — Causes which can account for the differences between the two line of cells are discussed.     

Replication kinetics of three DNA sequence families in synchronized mouse cells

Balb/C3T3 cells entered the quiescent Go state following serum deprivation. On addition of fresh serum, more than 95% of the culture resumed growth, but with asynchronous kinetics. If hydroxyurea were added just before the first cells reached S phase, at at least 90% of the cells accumulated at the Gl/S border over the next ten hours. When the block was removed, the culture moved synchronously into S phase. As the cells traversed S, the replication kinetics of three classes of rapidly renaturing DNA were analyzed. Main band highly repeated DNA and foldback DNA replicated continuously, In contrast, satellite DNA replication did not commence until three hours into S, whereupon its rate of synthesis increased ver rapidly, reaching a maximum with the next two hours. These results are discussed in the light of earlier work utilizing other methods of cell synchronization.     

Early cellular responses to diverse growth stimuli independent of protein and RNA synthesis.

Serum, elevated pH, excess Zn++, 9,10 dimethyl-1,2 dibenzanthracene (DMBA) and insulin accelerate the progress of growth-inhibited chick embryo cells into the S-period of DNA synthesis. A comparative study was made of their capacity to elicit other cellular responses within two hours after their application. All the agents studied stimulated the uptake of the glucose analogue 2-deoxy-D-glucose (2-dGlc). Elevated pH elicited a more striking increase than the other agents in the uptake of the amino acid analogue alpha-amino isobutyric acid (AIB). The application of subtoxic concentrations of Zn++ or DMBA did not stimulate the uptake of uridine by cells nor its incorporation into RNA when tested at 2 hours. However, it was found that the stimulation of uridine utilization did occur but was delayed several hours. Similarly, the accelerated onset of DNA synthesis was also delayed for several hours by these agents. Insulin acted like serum in stimulating the utilization of 2-dGlc, AIB and uridine. Serum and DMBA were particularly effective in stimulating the utilization of choline. It was concluded that the utilization of 2-dGlc, uridine and thymidine are affected similarly by all the agents, but that there may be differential effects in the utilization of AIB and choline. The inhibition of RNA synthesis by actinomycin D did not prevent the relative stimulation of 2-dGlc, AIB and choline utilization by serum and pH treatment. The inhibition of protein synthesis by cycloheximide did not prevent the relative stimulation of 2-dGlc and choline utilization by serum and pH treatment. It partially blocked the increased uptake of AIB and had erratic effects on the utilization of uridine. It was concluded that neither RNA nor protein synthesis is required for some, if not all, the early responses to growth stimuli measured here. The inhibited cell appears to be a poised system which carries out a programmed array of reactions characteristic of the cell type following perturbation by a variety of unrelated agents. In vivo specificity is provided by the physiological reagents available (i.e., hormones) and their capacity to interact with different cell types.