Premature chromosome condensation in a ts DNA-mutant of BHK cells

A temperature-sensitive mutant of BHK, designated is BN-2, shows a rapid drop in ³H-thymidine incorporation along with accumulation of the cells in the G1 phase of the cycle when asynchronous cultures are shifted from 33.5°C to the nonpermissive temperature of 39.5°C. Synchronized cultures of ts BN-2 cells did not enter DNA synthesis when shifted up in G1. Shift-up of cultures at the beginning of the S phase resulted in an approximately normal rate of DNA synthesis for about 2 hr. The rate of DNA synthesis then quickly declined, and the cells became arrested in mid-S after completion of approximately 0.5 rounds of DNA replication. At the same time, the majority of the cells were observed to lose the nuclear membrane and displayed premature chromosome condensation. These events were followed by the appearance of cells containing several micronuclei and eventual cell disruption and death. The nonpermissive temperature appeared to have no effect on either the elongation of short fragments of DNA or the execution of mitosis after the completion of the S phase under permissive conditions. The ts defect in this mutant may directly limit the initiation of DNA synthesis or alter the regulation of chromatin condensation.     

Time of replication of genes responsible for a temperature-sensitive function in a cell cycle-specific ts mutant from a hamster cell line

A method involving short pulses of 5-bromodeoxyuridine (brUdRib) followed by irraidation with 313 nm light was used to locate the time of replication of certain genes during the cell cycle of two cell lines, AF8 and AL106. AF8, a temperature-sensitive mutant of BHK21/13 cells, grows at 33°C but not at 39.5°C. AL106, a hybrid clone of tsAF8 and SV-40 transformed Lesch-Nyhan fibroblasts (LNSV), which retains all hamster chromosomes and one human chromosome (No. 3), has the ability to grow at 39.5°C. AF8 and AL106 cells synchronized at the G₁-S boundary were released from their block and pulsed with brUdRib for 2-hour periods during the S phase. The cells were subsequently irradiated with 313 nm light. Colony-forming efficiency and revertants frequency were studied. Incorporation of brUdRib during the early S phase (0–4 hours from the begining of S), decreased the colony-forming efficiency of AL106 cells both at 33°C and 39.5°C, and also of AF8 cells at 33°C. No AF8 colonies grew at the nonpermissive temperature regardless of the treatment. Thus the time of replication of genes responsible for colony-forming ability was the same in tsAF8 at the permissive temperature and in AL106 at both temperatures. The time of replication of the genes responsible for the ts function in AF8 cells was located by determining the revertants frequency in synchronized AF8 cells pulsed with brUdRib and irradiated during 1- to 2-hour periods of the S phase. Back-mutants were scored by counting the number of clones capable of growing at 39.5°C (nonpermissive for AF8 cells). The highest frequency of induced back-mutations occurred in synchronized AF8 cells pulsed with brUdRib (and irradiated) between two to four hours from the begining of the S phase. Exposure to brUdRib during other periods of the S phase or during G₁ had no effect on the reversion rate. This method can be used to locate the time of replication (in S) of ts genes in other temperature-sensitive mutants or of other specific genes in other conditional mutants.     

Histone protein and DNA synthesis in HeLa cells after thermal shock

Exposure of suspension-cultured HeLa cells to a 45° thermal shock resulted in cell inactivation and inhibition of both protein and DNA synthesis. DNA synthesis was inhibited in a biphasic manner with a more sensitive (D₀ = 7 min) and a less sensitive (D₀ = 20 min) phase. The less sensitive process was demonstrated to be DNA chain elongation. Transport of thymidine into intracellular pools was significantly less sensitive to thermal shock (D₀ in excess of 200 min). When HeLa cells were heated at 45° for 15 min there was an 80% inhibition of incorporation of precursors into both DNA and protein with little effect on precursor transport into cellular pools. While the rate of synthesis of whole cell and histone protein (H2a, H2b, H3, and H4) and DNA chain elongation recovered by 6 h after cell heating, total precursor incorporation into DNA was only 0.4 of control levels. The long-term depression of the DNA synthetic rate could not be explained by a cell cycle redistribution, a depression in the total fraction of S phase cells synthesizing DNA, or by a depression in the rate of DNA chain elongation. We conclude that thermal shock results in a long-term depression in the fraction of cell replicons involved in DNA replication.     

DNA crosslinks and DNA replication in mouse FM3A cells after treatment with 8-methoxypsoralen plus near-ultraviolet radiation

The rate of DNA-chain elongation was studied in mouse FM3A cells after treatment with 8-methoxypsoralen plus near-ultraviolet radiation using the minimal doses (1 μg/ml 8-methoxypsoralen plus 1–2.5 kJ/m² of near-ultraviolet radiation) which inhibited cell-cycle progression or DNA replication. A rapid decrease in incorporation of [³H]thymidine and recovery to some extent during incubation after treatment have been reported (Hyodo, M., Fujita, H., Suzuki, K., Yoshino, K., Matsuo, I. and Ohkido, M. (1982) Mutat. Res. 94, 199–211). The results of the present study showed that the rate was not changed suggesting that the decrease in [³H]thymidine incorporation was not due to the rate of DNA-chain elongation, but was due to change in the frequency of initiation of replication. Formation of DNA crosslinks was then studied by the sedimentation of pre-labeled DNA in an alkaline sucrose gradient. The results showed that, at these doses of 8-methoxypsoralen plus near-ultraviolet radiation, approx. 2–7 crosslinks were formed per 10⁹ Da. It was also suggested that some of the DNA crosslinks might be repaired during the prolonged incubation, but unrepaired crosslinks were still present after 24 h incubation.     

Characterization of DNA replication at a restrictive temperature in a mouse DNA temperature-sensitive mutant, tsFT20 strain, containing heat-labile DNA polymerase alpha activity

tsFT20 cells derived from a mouse mammary carcinoma cell line FM3A have temperature-sensitive DNA polymerase alpha activity (Murakami, Y., Yasuda, H., Miyazawa, H., Hanaoka, F., and Yamada, M. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 1761-1765). DNA replication in tsFT20 cells at the restrictive temperature (39 degrees C) has been characterized in detail. DNA-synthesizing ability of these cells was measured by [3H] thymidine incorporation and autoradiography. The incorporation of [3H]thymidine decreased rapidly after temperature shift-up, and the incorporation was less than 20% of the initial level after 4 h at 39 degrees C. The rapid decrease correlated well with the decrease in the grain number in the individual nucleus but not with the number of cells with labeled nuclei. Alkaline sucrose gradient sedimentation analysis and DNA fiber autoradiography revealed that DNA chain elongation proceeded normally within a replicon in the temperature-sensitive cells incubated at the restrictive temperature and the DNA elongation rate did not change during the incubation at the restrictive temperature up to at least 6 h. On the other hand, the maturation of replicon-sized DNA to higher molecular weight DNA was retarded or inhibited in the temperature-sensitive cells at the restrictive temperature. The analysis of the center to center distance between replicons by DNA fiber autoradiography revealed that the frequency of replicon initiation decreased in tsFT20 cells at 39 degrees C.     

Effects of temperature changes on thymidine kinase in heat- and cold-sensitive cell-cycle mutants and ‘wild-type’ murine P-815 cells

Two heat-sensitive (arrested in G1 at 39.5°C) and two cold-sensitive (arrested in G1 at 33°C) clonal cell-cycle mutants that had been isolated from the same clone (K 21), of the murine mastocytoma P-815 cell line, were tested for thymidine kinase (EC 2.7.1.21) activity. After shift of mutant cells to the nonpermissive temperature, thymidine kinase activity decreased, and minimal levels (i.e., less than 3% of those observed for ‘wild-type’ K 21 cells at the respective temperature) were attained within 16 h in heat-sensitive and after 3–4 days in cold-sensitive mutants, which is in good agreement with kinetics of accumulation of heat-sensitive and cold-sensitive cells in G1 phase. After return of arrested mutant cells to the permissive temperature, thymidine kinase of heat-sensitive cells increased rapidly and in parallel with entry of cells into the S phase. In cultures of cold-sensitive cells, however, initiation of DNA synthesis preceded the increase of thymidine kinase activity by approx. one cell-cycle time. Thymidine kinase activities in revertants of the heat-sensitive and cold-sensitive mutants were similar to those of ‘wild-type’ cells. In ‘wild-type’ K 21 cells incubated at 39.5°C, thymidine kinase activity was approx. 30% of that at 33°C. This difference is attributable, at least in part, to a higher rate of inactivation of the enzyme at 39.5°C, as determined in cultures incubated with cycloheximide. The rapid increase of thymidine kinase activity that occurred after shift of K 21 cells and of arrested heat-sensitive mutant cells from 39.5°C to 33°C was inhibited by actinomycin D and cycloheximide.     

Characterization of DNA synthesis and DNA-dependent ATPase activity at a restrictive temperature in temperature-sensitive tsFT848 cells with thermolabile DNA helicase B.

A temperature-sensitive mutant defective in DNA replication, tsFT848, was isolated from the mouse mammary carcinoma cell line FM3A. In mutant cells, the DNA-dependent ATPase activity of DNA helicase B, which is a major DNA-dependent ATPase in wild-type cells, decreased at the nonpermissive temperature of 39 degrees C. DNA synthesis in tsFT848 cells at the nonpermissive temperature was analyzed in detail. DNA synthesis measured by incorporation of [3H]thymidine decreased to about 50% and less than 10% of the initial level at 8 and 12 h, respectively. The decrease in the level of thymidine incorporation correlated with a decrease in the number of silver grains in individual nuclei but not with the number of cells with labeled nuclei. DNA fiber autoradiography revealed that the DNA chain elongation rate did not decrease even after an incubation for 10 h at 39 degrees C, suggesting that initiation of DNA replication at the origin of replicons is impaired in the mutant cells. The decrease in DNA-synthesizing ability coincided with a decrease in the level of the DNA-dependent ATPase activity of DNA helicase B. Partially purified DNA helicase B from tsFT848 cells was more heat sensitive than that from wild-type cells. Inactivation of DNA-dependent ATPase activity of DNA helicase B from mutant cells was considerably reduced by adding DNA to the medium used for preincubation, indicating that the DNA helicase of mutant cells is stabilized by binding to DNA.     

Control of DNA polymerase α, β and γ activities in heat- and cold-sensitive mammalian cell-cycle mutants

Two heat-sensitive (arrested in G₁ at 39.5°C) and two cold-sensitive (arrested in G₁ at 33°C) clonal cell-cycle mutants of the murine P-815-X2 mastocytoma line were tested for DNA polymerase α, β and γ activities. After transfer of mutant cells to the respective nonpermissive temperature, DNA polymerase α activities decreased more slowly than relative numbers of cells in S phase. Furthermore, numbers of DNA-synthesizing cells decreased to near-zero levels, whereas polymerase α activities in arrested cells were as high as 15–40% of control values. After return of arrested cells to the permissive temperature, polymerase α activities increased essentially in parallel with relative numbers of cells in S phase. In contrast to the changes in thymidine kinase (Schneider, E., Müller, B. and Schindler, R. (1983) Biochim. Biophys. Acta 741, 77–85), the decrease of polymerase α during entry of cells into proliferative quiescence thus appears to be under rather relaxed control, while after return of arrested cells to the permissive temperature the increase in polymerase α is tightly coupled with reentry of cells into S phase. For DNA polymerase β and γ activities, no obvious correlation with changes in the proliferative state of cells was detected.     

Discontinuous replication of colicin E1 plasmid DNA in a cell extract containing thermolabile DNA ligase.

A cell extract prepared from the lig-ts7 mutant of Escherichia coli is able to carry out a complete round of DNA replication of colicin E1 plasmid at 25 °C. However, the apparent rate of elongation of the progeny strands at this temperature is much smaller than in an extract from the thermoresistant revertant cells. Chain elongation in the lig-ts extract is depressed by raising the incubation temperature from 25 °C to 32 °C, whereas that in the lig⁺ revertant extract is not. The rate of closure of the progeny strands of newly formed open circular molecules is also reduced in the lig-ts extract, even at 25 °C.The DNA pulse-labelled with the lig-ts extract for 30 seconds at 32 °C contains a large amount of short DNA fragments of approximately 7 S, in addition to DNA chains of various sizes between 7 S and 17 S (unit length). Most of these replicating molecules are converted to completely replicated closed circular molecules upon chasing with a lig⁺ extract. DNA-DNA hybridization experiments show that molecules replicated to various extents contain 7 S DNA fragments of both strands, but more of the L-strand component, whose 5′-to-3′ direction corresponds to the overall direction of unidirectional replication. The longer DNA chains are enriched in the H-strand component.The cell extracts used for the plasmid DNA replication have an activity which converts alkali-labile closed circular plasmid DNA containing apurinic sites to alkali-stable closed circular molecules. Addition of nicotinamide mononucleotide leads to conversion of the alkali-labile DNA to open circular molecules. In the replication system with the cell extract, however, the compound does not interfere with elongation of progeny strands. Chain elongation in the lig-ts extract at 25 °C is not significantly affected by nicotinamide mononucleotide. Thus, the 7 S DNA fragments formed with the lig-ts extract are unlikely to be generated as a result of incomplete repair of misincorporated nucleotides. We conclude that both strands of colicin E1 plasmid DNA replicate discontinuously.     

DNA synthesis in Hela cells at low temperature

It has been proved that ³H-thymidine is incorporated into DNA of HeLa cells cultured at 4 °C and its labelling distribution in DNA is homogeneous. This incorporation of ³H-thymidine increased with the duration of incubation and only 30% of the cell population was labelled after 12 h. When synchronous cell populations were used, the rate and extent of DNA synthesis at 4 °C was proportional to the relative number of cells in S phase at that temperature. Thus, cellular labelling at 4 °C does not result from a non-specific absorption phenomenon, but indicates a DNA synthesis process.     

Characterization of a ts mutant of BALB/3T3 cells and correction of the defect by in vitro addition of extracts from wild-type cells.

ts20 is a temperature-sensitive mutant cell line derived from BALB/3T3 cells. DNA synthesis in the mutant decreased progressively after an initial increase during the first 3 h at the restrictive temperature. RNA and protein synthesis increased for 20 h and remained at a high level for 40 h. Cells were arrested in S phase as determined by flow microfluorimetry, and DNA chain elongation was retarded as measured by fiber autoradiography. Infection with polyomavirus did not bypass the defect in cell DNA synthesis, and the mutant did not support virus DNA replication at the restrictive temperature. After shift down to the permissive temperature, cell DNA synthesis was restored whereas virus DNA synthesis was not. Analysis of virus DNA synthesized at the restrictive temperature showed that the synthesis of form I and replicative intermediate DNA decreased concurrently and that the rate of completion of virus DNA molecules remained constant with increasing time at the restrictive temperature. These studies indicated that the mutation inhibited ongoing DNA synthesis at a step early in elongation of nascent chains. The defect in virus and cell DNA synthesis was expressed in vitro. [3H]dTTP incorporation was reduced, consistent with the in vivo data. The addition of a high-salt extract prepared from wild-type 3T3 cells preferentially stimulated the incorporation of [3H]dTTP into the DNA of mutant cells at the restrictive temperature. A similar extract prepared from mutant cells was less effective and was more heat labile as incubation of it at the restrictive temperature for 1 h destroyed its ability to stimulate DNA synthesis in vitro, whereas wild-type extract was not inactivated until incubated at that temperature for 3 h.     

Use of low temperature for growth arrest and synchronization of human diploid fibroblasts

The growth kinetics of human diploid fibroblasts at two different temperatures were followed. Proliferation of exponentially growing cells is reduced and eventually stops upon incubation at low temperature (i.e. 30°C). The cells which are in S phase at the time of switching to low temperature complete their DNA synthesis and become arrested in the G₁ phase of the cell cycle. The arrested cells can be stimulated to proliferate by restoration of the optimal growth temperature (37°C). The kinetics of entry into S phase were investigated by measuring [³H]thymidine incorporation into TCA-precipitable material, by autoradiography and by flow cytofluorimetry. The synchronized cells initiate DNA synthesis at approximately 8 h and DNA synthesis peaks at 20.4±0.7 h after stimulation.In addition, the rates of UV-induced excision repair at 30°C and 37°C were compared. The results indicate that at 30°C the excision-repair process is operative but at a slightly reduced rate in comparison with repair at 37°C.This method will be useful for the study of S-phase-dependent processes, as well as for repair studies in the absence of cell division.     

Transcriptional activity and chromatin structural changes in a temperature-sensitive mutant of BHK cells blocked in early G1.

AF8, a temperature-sensitive mutant of BHK $\text{21}\text{13}$ cells, has been shown to arrest at the non-permissive temperature in the G1 phase of the cell cycle. When AF8 cells are released from density-dependent arrest of growth by trypsinization and replating at lower density, 60–80% of the cells enter DNA synthesis and divide at the permissive temperature (33 °C), while only 20% enter DNA synthesis at the non-permissive temperature (39.5 °C). The temperature-sensitive block has been localized 4 to 8 h before the onset of DNA synthesis which begins at 12 h after stimulation. Two biochemical events of the prereplicative phase have been temporally related to this temperature-sensitive block. RNA synthesis as measured in isolated nuclei increases initially at both temperatures, then levels off and declines to control levels at 39.5 °C while continuing to increase at 33 °C. Parallel changes are found in circular dichroism spectra and ethidium bromide binding capacity of isolated chromatin. The results suggest that these biochemical changes are involved in the regulation of the prereplicative phase and the subsequent entrance of cells into DNA synthesis.     

Control of Saccharomyces cerevisiae 2microN DNA replication by cell division cycle genes that control nuclear DNA replication.

The replication of the 2 μm DNA of Saccharomyces cerevisiae has been examined in cell division cycle (cdc) mutants. The 2 μm DNA does not replicate at the restrictive temperature in cells bearing the cdc28, cdc4, and cdc7 mutations which prevent passage of cells from the G1 phase into S phase. Plasmid replication also is prevented in a mating-type cells by α factor, a mating hormone which prevents cells from completing an event early in G1 phase. The 2 μm DNA ceases replication at 36 °C in a mutant harboring the cdc8 mutation, a defect in the elongation reactions of nuclear DNA replication. Plasmid replication continues at the restrictive temperature for approximately one generation in a cdc13 mutant defective in nuclear division. These results show that 2 μm DNA replication is controlled by the same genes that control the initiation and completion of nuclear DNA replication.     

Further characterization of a murine temperature-sensitive mutant, tsFT20 strain, containing heat-labile DNA polymerase alpha-activity

tsFT20 cells, which have temperature-sensitive DNA polymerase alpha-activity, were characterized mainly at the cellular level. The cells lost their ability to synthesize DNA immediately after a shift to non-permissive temperature. The extent of decrease in the activity of DNA polymerase alpha in whole-cell extracts was the same as that of the decrease in the DNA replication ability determined by [3H]thymidine incorporation. At 39 degrees C, tsFT20 cells lost most of their colony-forming ability in one doubling time (16 h). The cells could not grow at higher than 38 degrees C, but could grow at 37 degrees C. When tsFT20 cells were synchronized at the G1/S boundary and incubated at 39 degrees C, they could not complete the S phase, ceasing cell cycle progression in mid-S phase. A temperature shift (33 degrees C----39 degrees C) experiment indicated that the whole S phase was temperature-sensitive, whereas the G2 and M phases were not. These results confirmed that DNA polymerase alpha plays a key role in DNA replication in mammalian cells.     

Murine temperature-sensitive DNA polymerase α mutant displays a diminished capacity to stimulate DNA synthesis in senescent human fibroblast nuclei in heterokaryons at the nonpermissive condition

We have investigated the capacity of a murine cell line with a temperature-sensitive (ts) mutation in the DNA polymerase α (Pola) locus and a series of ts non-Pola mutant cell lines from separate complementation groups to stimulate DNA synthesis, in senescent fibroblast nuclei in heterokaryons. In the Pola mutant × senescent heterodikaryons, both human and murine nuclei display significantly diminished levels of DNA synthesis at the restrictive temperature (39.5°C) as determined by [³H]thymidine labeling in autoradiographs. In contrast, all of the non-Pola mutants, as well as the parental (wild-type) murine cells, induced similar levels of DNA synthesis in both parental nuclei at the nonpermissive and permissive temperatures. Similarly, young human fibroblasts are also able to initiate DNA synthesis in heterokaryons with the ts Pola mutant at the two temperatures. In order to determine if complementation of the non-Pola mutants requires induction of serum responsive factors in the senescent cells, fusion studies of similar design were conducted with young and old human fibroblasts incubated in low serum (0.2%) for 48 hr prior to and after cell fusion. Again, a diminished level of DNA synthesis was observed at 39.5°C in the Pola mutant x senescent cell heterokaryons. In these low-serum studies, both parental nuclei in the Pola x young cell heterokaryons and the human nuclei in heterokaryons with one of the non-Pola mutants (FT107) also displayed diminished levels of DNA synthetic activity. All of the other mutants are able to support similar levels of synthetic activity at both temperatures in the presence of reduced serum. The nature of the mutation in three of the non-Pola lines has not been determined but, like the Pola mutant cells, are inhibited in the G₁ phase of the cell cycle when incubated at the nonpermissive temperature (39.5°C). The fourth non-Pola mutant line is known to have at least one ts mutation in the cdc2 gene and is inhibited in the G₂ phase when exposed to 39.5°C. These results suggest that there may be a functional deficiency of pol α in senescent human fibroblasts, and this replication factor may be one of the rate-limiting factors involved in loss of the capacity to initiate DNA synthesis in senescent cells. © 1994 Wiley-Liss, Inc.     

The initiation and elongation steps in protein synthesis: Relative rates in chinese hamster ovary cells during and after hyperthermic and hypothermic shocks

The relative rates of the initiation and elongation phases of protein synthesis have been determined in heat- and cold-shocked CHO cells from measurements of the incorporation of ³⁵S-methionine into N-terminal and internal positions of growing peptides by a modified Edman degradation. When the cells are shifted from 37°C to temperatures between 10°C and 34°C, the rate of initiation is at first reduced more extensively than that of elongation. After 20 to 30 minutes at the lower temperature, however, the cells undergo a metabolic adjustment which includes increasing the rate of initiation until it corresponds to the rate of elongation at that temperature. Calculated apparent energies of activation for initiation and elongation are in reasonable agreement with those determined in other mammalian cells. When the cooled cells are returned to 37°C, the rates of initiation and elongation recover immediately but do not exceed the control values. Exposure to elevated temperature (43°C) causes an immediate cessation of initiation and thus a delayed inhibition of elongation; upon return to 37°C, the rate of initiation is transiently elevated above the control rate, and the rate of elongation returns to the control rate after a 2- to 3-minute delay. Hence, a factor which leads to supranormal rates of initiation may accumulate at high but not at low temperatures.     

Properties of ts Cl mouse L cells which exhibit temperature-sensitive DNA synthesis.

ts Cl mouse L cells are temperature-sensitive (ts) in DNA synthesis. The protein involved undergoes inactivation at 38.5 °C, with an apparent half-life of 3–4 h. A variety of experimental approaches yield data indicating that the ts Cl gene product acts directly during the DNA-synthesis period, probably late during the duplication of chromosomal DNA. The specificity of the ts lesion is reflected in the fact that replication of mitochondrial DNA is unaffected for many hours after nuclear DNA synthesis is almost totally inhibited. Temperature inactivation is not due to degradation or to loss of template capacity of preformed DNA. ts Cl cells are able to enter a DNA-synthesis phase at the higher temperature, as indicated by radioautographic experiments and by studies in which cells, blocked at the permissive temperature (34 °C) in a pre-DNA synthesis phase by isoleucine deprivation, are subsequently incubated at 38.5 °C. Cells arrested early in DNA synthesis by hydroxyurea treatment at 34 °C continue such synthesis for a short interval after up-shift to 38.5 °C. However, they are then unable to complete the S phase in progress nor can they proceed into cell division. The kinetics of DNA synthesis in cells incubated at 38.5 °C and back-shifted to 34 °C are compatible with the model that the ts Cl locus encodes an S phase function.     

Isolation of temperature-sensitive cell cycle mutants from mouse FM3A cells. Characterization of mutants with special reference to DNA replication

A large number of mutants that are temperature sensitive (ts) for growth have been isolated from mouse mammary carcinoma FM3A cells by an improved selection method consisting of cell synchronization and short exposures to restrictive temperature. The improved method increased the efficiency of isolating DNA ts mutants, which showed a rapid decrease in DNA-synthesizing ability after temperature shift-up. Sixteen mutants isolated by this and other methods were selected for this study. Flow microfluorometric analysis of these mutants cultured at a nonpermissive temperature (39 degrees C) for 16 h indicated that five clones were arrested in the G1 to S phase of the cell cycle, six clones were in the S to G2 phase, and two clones were arrested in the G2 phase. The remaining three clones exhibited 8C DNA content after incubation at 39 degrees C for 28 h, indicating defects in mitosis or cytokinesis. These mutants were classified into 11 complementation groups. All the mutants except for those arrested in the G2 phase and those exhibiting defects in mitosis or cytokinesis showed a rapid decrease in DNA synthesis after temperature shift-up without a decrease in RNA and protein synthesis. The polyomavirus DNA cell-free replication system, which consists of polyomavirus large tumor antigen and mouse cell extracts, was used for further characterization of these DNA ts mutants. Among these ts mutants, only the tsFT20 strain, which contains heat-labile DNA polymerase alpha, was unable to support the polyomavirus DNA replication. Analysis by DNA fiber autoradiography revealed that DNA chain elongation rates of these DNA ts mutants were not changed and that the initiation of DNA replication at the origin of replicons was impaired in the mutant cells.     

Regulation of DNA replication by serum and the transforming function in cultured rat fibroblasts transformed by Rous sarcoma virus.

The onset and rate of semiconservative DNA replication were measured in stimulated cultured rat fibroblasts and their Rous sarcoma virus-transformed derivatives after a period of serum deprivation. Rat-1 (tsLA24/RSV) cells initiated DNA synthesis following a shift to the permissive temperature or addition of serum at the non-permissive temperature. Their rate of DNA replication was unaffected by the presence of serum at the permissive temperature, however, there was a serum requirement at the non-permissive temperature. The transition probability was less at the permissive temperature, independent of serum, than at the non-permissive temperature in the presence of serum. The amount of DNA induced to replicate by addition of serum at the non-permissive temperature or by a shift to the permissive temperature was similar. Using the untransformed Rat-1 cells and these cells transformed by wild-type RSV (Rat-1 (wt/RSV)), it was confirmed that the rate of entry into S phase (transition probability) was always lower in the transformed cell line at both 39° and 35°. In both cell lines the rate of DNA replication was independent of temperature, but the onset was delayed at the lower temperature. These results indicate that in the cell lines examined, (1) serum was able to commit the cells to replicate DNA (alter the transition probability) in both transformed and untransformed cells, but the transforming function was able to supplant a serum-dependent process during G₁ necessary for the initiation of DNA replication, and (2) the effects of the transforming function and serum factor(s) on the alteration of the transition probability are not additive, suggesting that the transforming function initiates a process which acts at the level of the commitment to DNA replication which may render the normal serum-related control mechanisms ineffective in the regulation of growth.