DNA replication in mammalian cells exposed to the action of physical, chemical or biological factors. IV. 5-fluorodeoxyuridine modifies the effect of hyperthermia on DNA synthesis and the survival of HeLa cells

Preliminary incubation of logarithmically growing HeLa cells with FUdR decreases an inhibitory effect of hyperthermia (43 degrees C, 1 hour) on DNA synthesis. The hyperthermia alone inhibits DNA synthesis considerably: the label in acid-precipitable material accounts for 30% of control level. Preliminary incubation of the cells with FUdR (10(-6)) for 24 or 6 hours (plus 18 hours in fresh medium) decreases the effect: the label yields account for 50 or 90% of the respective control levels. A molecular weight of nascent DNA synthetized in the cells after hyperthermia or incubation with FUdR is lower than the control one but it increases rapidly during postincubation. Nucleoid of cells treated with FUdR has a sedimentation velocity which exceeds that of the control cells by more than 25%. Preliminary incubation with FUdR sensitizes the cells to hyperthermia. The effect is not believed to be associated with cells synchronization since the treatment of the cells with FUdR for 2 or 6 hours, when FUdR itself does not exert its toxic effect, brings about sensibilization of cells to hyperthermia. It is suggested that modification of the cell viability and DNA replication are related to some changes of chromatine structure induced by FUdR.     

DNA replication in mammalian cells after the action of factors of a physical, chemical or biological nature. V. The structural reorganization of replicating DNA in HeLa cells after incubation with 5-fluorodeoxyuridine

A study was made of sedimentation properties of the nucleoid (chromatin) of HeLa cells with radio- and thermostable mode of DNA synthesis induced by 5-fluorodeoxyuridine (FUdR). After the incubation of HeLa cells with FUdR (10(-6) M, 6 h or 24 h) the rate of nucleoid sedimentation was shown to rise by 40 and 25%, respectively. Maximum relaxation of the nucleoid was observed under 5 mg/ml ethidium bromide concentration in sucrose gradients. After the incubation with FUdR the nucleoid relaxes to a lesser extent, and after irradiation its response to ethidium bromide in various concentrations was similar to that of intact nucleoid, and by this property the "FUdR nucleoid" differs essentially from the irradiated "normal nucleoid". A model of chromatin structure of cells exposed to FUdR is proposed, based on the transformation of large domains in small ones, for the explanation of radioresistant DNA synthesis.     

DNA replication in mammalian cells after the action of physical, chemical or biological factors. VI. The recovery of DNA synthesis in a culture of irradiated cells

The kinetics of DNA synthesis restoration in cultured HeLa cells and in L-929 mouse fibroblasts irradiated by gamma-rays of 60Co with a dose of 10 Gy was studied. Early after irradiation the rate of DNA synthesis in HeLa cells measured with 3H-thymidine incorporation was seen to decrease. Two hours later the incorporation starts to increase to reach the control level 4 hours after irradiation and then becomes even higher than this level. The distribution of cells among phases of the cell cycle measured with flow cytometry undergoes changes. 4-6 hours after irradiation part of S-phase cells increased contributing presumably to the elevating of 3H-thymidine incorporation observed at this time. The restoration of the incorporation was suppressed by inhibitors of protein and RNA synthesis--cycloheximide and actinomycin D. It is suggested that the processes of restoration of DNA synthesis in irradiated cells can be of inducible nature. In irradiated HeLa and L-929 cells the restoration of DNA synthesis is resistant to novobiocin, an inhibitor of DNA replication.     

Reorganization of DNA replicating system induced by 5-fluorodeoxyuridine and caffeine as the basis for radiosensitivity in human calls

Treatment of diploid human fibroblasts with 5-fluorodeoryuridine (FUdR) and caffeine results in the increase in cellular radiosensitivity in terms of survival and chromosomal aberrations, on the one hand, and in radioresistant DNA synthesis (RDS), on the other hand, i.e. rather mimics those in mutant cells from patients with AT, XPII, Down syndrome, and others. A study was made of the autoradiographic length of simultaneously active adjacent replicon clusters. After incubation of diploid human cells with FUdR (10(-6) M, 6 h), this parameter was shown to reduce by two-fold, remaining unchanged upon 5 Gy irradiation. In contrast, after incubation of the cells with caffeine (2 mM, 30 min), this parameter was longer, compared to that in intact cells; upon 5 Gy irradiation the values remained almost the same as in the control. A possible relation of the data to the cellular radiosensitivity and RDS in the cells incubated with FUdR and caffeine is discussed.     

Cytotoxicity and genotoxicity testing of sodium fluoride on Chinese hamster V79 cells and human EUE cells.

The cytotoxic effects of sodium fluoride (NaF) on hamster V79 cells and human EUE cells were studied by measuring the cloning efficiency and DNA, RNA and protein synthesis in cells cultured in the presence of NaF. Potential mutagenicity of NaF was followed on the basis of induced 6-thioguanine-resistant mutants in treated Chinese hamster V79 cells. The results showed that the addition of 10-150 micrograms of NaF per ml of culture medium induced 10-75% cytotoxic effect on hamster V79 cells but had no toxic effect on human EUE cells. NaF was cytotoxic to human EUE cells at considerably higher concentrations (200-600 micrograms/ml). Growth of both cell types with 100 and 200 micrograms of NaF per ml caused inhibition of 14C-thymidine, 14C-uridine and 14C-L-leucine incorporation. This means that NaF inhibits macromolecular synthesis whereby damaging effects were less drastic in human EUE cells. The results of detailed mutagenicity testing on hamster V79 cells showed that NaF did not show any mutagenic effect after long-term (24-h) incubation of hamster cells in the presence of 10-400 micrograms of NaF per ml of culture medium.     

Rate and time of DNA synthesis of individual Chinese hamster cells.

The duration of DNA synthesis of a diploid cell line of Chinese hamster fibroblasts was determined in a comparative study by the FLM technique, and also by a new technique for measuring the rate of DNA synthesis of individual cells. These methods produced comparable results when applied during exponential growth of the cells. The rate of DNA synthesis was measured by means of quantitative autoradiography following a short-term incubation of the cells with 5 X 10(-6) M FUdR and 10(-5) M 14C-TdR. The choice of the medium for this purpose did not seem to be critical. The autoradiographic silver grains over cells and 14C-standard sources are counted by microphotometry using incident light bright-field. The direct measurements of DNA synthesis rate are 'compartment' statistics which have been converted into 'flux' parameters for comparison with the FLM method and applicability in cell-kinetic calculations. Frequency distributions of the rate of DNA synthesis of individual cells thus obtained may resemble normal distributions quite closely. They result from several factors: differences in the rate of synthesis in different parts of the S-phase, the density distribution of cells within the S-phase, the variation in the time of DNA synthesis among individual cells, and the experimental error. In the case of a pronounced partial synchronization as probably has been present in one experiment performed in the lag phase, an incorrect time of DNA synthesis may result from the rate values. Due to the variation in DNA synthesis rate in different parts of the S-phase it is not possible to determine the duration of DNA synthesis of an individual cell. However, the mean values of DNA synthesis time are reliable. The new method will be preferentially applied for determining the duration of DNA synthesis of human cells in as far as difficulties are encountered with the classical methods. In addition, it may be used to advantage for studying cells which make up low percentages in mixed populations. It finally permits a safer morphological classification of the cells under study than is possible with the classical methods.     

The relationship between DNA strand-scission and DNA synthesis inhibition in HeLa cells treated with neocarzinostatin.

Neocarzinostatin inhibits DNA synthesis in HeLa S3 cells and induces the rapid limited breakage of cellular DNA. The fragmentation of cellular DNA appears to precede the inhibition of DNA synthesis. Cells treated with drug at 37 degrees C for 10 min and then washed free of drug show similar levels of inhibition of DNA synthesis or cell growth, or of strand-scission of DNA as when cells were not washed. If cells are preincubated with neocarzinostatin at 0 degrees C before washing, the subsequent incubation of 37 degrees C results in no inhibition of DNA synthesis or cell growth, or cutting of DNA. Isolated nuclei or cell lysates derived from neocarzinostatin-treated HeLa S3 cells are inhibited in DNA synthesis but this can be overcome in cell lysates by adding activated DNA. A cytoplasmic fraction from drug-treated cells can stimulate DNA synthesis by nuclei isolated from untreated cells, whereas nuclei from drug-treated cells are not stimulated by the cytoplasmic fraction from untreated cells. By contrast, neocarzinostatin does not inhibit DNA synthesis when incubated with isolated nuclei, but it can be shown that under these conditions the DNA is already degraded and is not further fragmented by the drug. These data suggest that the drug's ability to induce breakage of cellular DNA in HeLa S3 cells is an essential aspect of its inhibition of DNA replication and may be responsible for the cytotoxic and growth-inhibiting actions of neocarzinostatin.     

Effects of cis-platinum(II) diamminedichloride on survival and the rate of DNA synthesis in synchronously growing HeLa cells in the absence and presence of caffeine

Synchronously growing HeLa cells demonstrated a different profile of DNA synthesis to that observed for Chinese hamster V79-379A cells after treatment with cis-Platinum(II) diamminedichloride (cis-Pt(II)) in the G₁ phase of the cell cycle. The progression of G₁ phase treated cells into the DNA synthetic phase was not affected. The peak rate of DNA synthesis in the first cycle was decreased in a dose dependent manner. However, no displacement in the time of appearance of this peak rate of DNA synthesis was observed in the first cycle as had been observed in Chinese hamster V79-379A cells. The timing of mitosis after the first cycle was delayed in a dose dependent manner and resulted in a concomitant delay in the appearance of the peak rate of DNA synthesis in the second cycle. The peak rate of DNA synthesis in the second cycle was reduced in a dose dependent manner. The ability of cells to divide after the first cycle was not related to their eventual ability to survive. Incubation of HeLa cells with caffeine after treatment with cis-Pt(II) did not increase the toxicity of cis-Pt(II). This was consistent with the lack of effect of caffeine posttreatment on the rate of DNA synthesis in cis-Pt(II) treated synchronously growing HeLa cells. HeLa cells did not show the characteristics of caffeine sensitive replication repair, nor did they show evidence for the presence of an inducible repair system. The rate of DNA synthesis, cell number and survival data were discussed in relation to a mechanism of cell death proposed for Chinese hamster cells.     

The action of caffeine on X-irradiated HeLa cells. VIII. Recovery from potentially lethal damage

Recovery from potentially lethal radiation damage in HeLa S3 cells has been studied by irradiating synchronous cultures with 4 Gy at selected ages in the cell cycle, initiating treatment with 4 mM caffeine, which prevents recovery, at progressively later times up to 24-30 h after irradiation, and determining the plateau level of survival after incubation with the caffeine until 36-40 h after mitotic collection. Cell recovery appears to begin immediately after irradiation at any time during interphase: an accelerating increase in survival gives way after several hours to a linear increase which lasts for an additional several hours. The median recovery time is approximately 13 h after irradiation at any time during G1, but is markedly shorter (5-7 h) after irradiation in S or G2. The rate of recovery is slightly depressed if DNA replication is inhibited with aphidicolin after irradiation and slightly enhanced if protein synthesis is inhibited with cycloheximide. Both the rate and the extent of recovery are dependent on the location of the cells in the cycle at the time of irradiation--both functions increasing with cell age from the beginning of S, but having different age dependencies in G1. Blocking cell progression with a DNA-synthesis inhibitor before irradiation halts the age-dependent changes.     

Fibre autoradiography of repair and replication in DNA from single cells: the effect of DNA synthesis inhibitors

DNA fibre autoradiography, after incorporation of high specific activity 3H-thymidine and 3H-deoxycytidine, has been used to investigate repair in DNA fibres from single cells following UV, or methyl-methane sulphonate (MMS) treatment. Asynchronously growing human fibroblasts, leucocytes, and HeLa cells at different phases of the cell cycle have been investigated. Isotope incorporation in repair could be differentiated from that involved in replication by the distribution and density of silver grains along the DNA fibres. Grain distribution due to repair was continuous over long stretches of the fibres and was at a low density, occasionally interspersed with short slightly denser segments. Replication labelling on the other hand, was dense and usually in short tandem segments. Repair labelling was of a similar overall density in fibres from a single cell, but differed in intensity from cell to cell. In mutagen treated Go (leucocytes) or G1 (HeLa cells), repair labelling was not increased by the presence of the DNA inhibitors, hydroxyurea (HU) or 5-fluorodeoxyuridine (FUdR). Repair was not detectable in S cells however, without the use of these inhibitors to reduce endogenous nucleoside production. FUdR enhanced the repair labelling in S cells only slightly, while HU increased it beyond that observed in UV irradiated, HU treated, G1 cells. The intensity of repair labelling in fibres from mutagen treated S cells appears to be proportional to the degree of reduction of DNA chain elongation in replicons.     

Accuracy of UV-induced DNA repair in V79 cells with imbalance of deoxynucleotide pools

Chemical mutagens generally cause nucleotide pool imbalance. We postulated that this effect might enhance the mutagenic effect by reducing the accuracy of DNA-repair synthesis. We used an inducer of DNA repair which causes minor pool modifications, namely UV light, and imbalanced the nucleotide pools by incubating UV-irradiated V79 cells with thymidine or deoxycytidine (10(-5)-10(-2) M) during the early phases of repair. The effects on pool sizes of the incubation with deoxynucleosides were determined by directly measuring the 4 deoxynucleoside triphosphates in cell extracts. The impairment of repair accuracy was evaluated by comparing the frequency of mutations at the HGPRT locus (induction of resistance to 6TG) in irradiated cells incubated with deoxynucleosides or allowed to carry on repair synthesis in nucleoside-free medium. Despite the marked imbalance of pyrimidine nucleotide pools, an increase of mutations was observed only with the highest concentrations of thymidine and deoxycytidine. Such an increase was much lower than that reported in the case of facilitation by excess nucleosides of chemically induced mutagenesis. The results indicate that UV-induced repair is scarcely affected by precursor biases.     

Caffeine-induced modulation of the lethal action of X rays on Chinese hamster V79 cells

Caffeine-mediated enhancement of the killing of V79 cells by 220-kV X rays at various times in the cell cycle was compared with that of HeLa cells by measuring (i) the dependence of cell survival on the duration of treatment with 5-10 mM caffeine, (ii) the effect of caffeine treatment on the X-ray dose-survival curve, and (iii) the loss of sensitivity to caffeine as a function of time after irradiation. The behavior of V79, while similar in many respects to that of HeLa (reported previously), differs in several ways. Caffeine treatment causes rapid killing immediately after irradiation irrespective of cell age, while HeLa is refractory in S phase and highly sensitive in G2. As with HeLa, the (multitarget) dose-survival curve parameters are reduced by caffeine treatment, but the age-dependent fluctuations in D0 are not eliminated as completely as with HeLa and the extrapolation number assumes values less than unity in the latter part of the cycle rather than in the early part. Loss of sensitivity to caffeine after irradiation early in the cycle appears to undergo a transient reversal in the middle of the cycle, a phenomenon not observed in HeLa.     

Ligase-deficient yeast cells exhibit defective DNA rejoining and enhanced gamma ray sensitivity.

Yeast cells deficient in DNA ligase were also deficient in their capacity to rejoin single-strand scissions in prelabeled nuclear DNA. After high-dose-rate gamma irradiation (10 and 25 krads), cdc9-9 mutant cells failed to rejoin single-strand scissions at the restrictive temperature of 37 degrees C. In contrast, parental (CDC9) cells (incubated with mutant cells both during and after irradiation) exhibited rapid medium-independent DNA rejoining after 10 min of post-irradiation incubation and slower rates of rejoining after longer incubation. Parental cells were also more resistant than mutant cells to killing by gamma irradiation. Approximately 2.5 +/- 0.07 and 5.7 +/- 0.6 single-strand breaks per 10(8) daltons were detected in DNAs from either CDC9 or cdc9-9 cells converted to spheroplasts immediately after 10 and 25 krads of irradiation, respectively. At the permissive temperature of 23 degrees C, the cdc9-9 cells contained 2 to 3 times the number of DNA single-strand breaks as parental cells after 10 min to 4 h of incubation after 10 krads of irradiation, and two- to eightfold more breaks after 10 min to 2.5 h of incubation after 25 krads of irradiation. Rejoining of single-strand scissions was faster in medium. After only 10 min in buffered growth medium and after 10 krads of irradiation, the number of DNA single-strand breaks was reduced to 0.32 +/- 0.3 (at 23 degrees C) or 0.21 +/- 0.05 (at 37 degrees C) per 10(8) daltons in parental cells, but remained at 2.1 +/- 0.06 (at 23 degrees C) or 2.3 +/- 0.07 (at 37 degrees C) per 10(8) daltons in mutant cells. After 10 or 25 krads of irradiation plus 1 h of incubation in medium at 37 degrees C, only DNA from CDC9 cells was rejoined to the size of DNA from unirradiated cells, whereas at 23 degrees C, DNAs in both strains were completely rejoined.     

Repair Replication and Photorepair of DNA in Larvae of DROSOPHILA MELANOGASTER

Repair replication of DNA has been studied in first instar larvae of Drosophila melanogaster with isopycnic centrifugation techniques. Larvae were fed BUdR, FUdR, streptomycin, penicillin, and Fungazone for two to four hours prior to exposure to UV, X-rays, MMS, or EMS. Feeding was continued for four hours in the presence of (3)HBUdR and DNA was isolated from whole larvae. Repair replication is stimulated by each of these agents. MMS is about 10 times as potent as EMS in stimulating repair synthesis. A dose of 200 ergs/mm(2) largely saturates the level of repair replication observed after UV irradiation. Repair replication rises between 0 and 80,000 R of X-rays before falling off. Semiconservative synthesis is seriously inhibited above a dose of 40,000 R of X-rays. Photorepair has been detected as a reduction in repair synthesis resulting from post-irradiation exposure to photoreactivating light. The same treatment has no detectable effect on X-ray-stimulated repair replication. Repair replication is insensitive to the presence of caffeine or hydroxyurea during the final incubation, although semiconservative synthesis is strongly inhibited by these agents. A mixture of BUdR and (3)HTdR can be used to replace (3)HBUdR in detecting repair replication.     

Nm23-H1 is responsible for SUMO-2-involved DNA synthesis induction after X-ray irradiation in human cells

Human cells derived from nevoid basal carcinoma syndrome (NBCCS) patients show increased levels of DNA synthesis activity after X-ray irradiation which is suggested to be casually related to reduction in cellular amounts of small ubiquitin-like protein modifier (SUMO-2/SMT-3A). In the present study, an increased level of DNA synthesis activity was found 8 h after X-ray irradiation in HeLa cells with reduction in SUMO-2 amounts by siRNA treatment for SUMO-2. When comparative proteomic analysis was performed between the siRNA and mimic control siRNA treated cells using two-dimensional (2D) electrophoresis and mass spectrometry, three proteins were identified as candidates. Our research focused on Nm23-H1, a nucleoside diphosphate kinase, whose amounts decreased after X-ray irradiation in HeLa cells treated with siRNA for SUMO-2. In the Nm23-H1 siRNA treated cells, induction of DNA synthesis was also detected. Furthermore, in synchronized HeLa cells, DNA synthesis was confirmed in the S phase. Moreover, increased expression of proliferating cell nuclear antigen (PCNA) was observed in Nm23-H1 siRNA treated HeLa cells after X-ray irradiation. In addition, Nm23-H1 was modified with SUMO-2 after X-ray irradiation. The present findings suggest that the reduction of Nm23-H1 is related to the decrease in sumoylation, which in turn, is involved in the induction of DNA synthesis via the regulation of PCNA expression after X-ray irradiation.     

DNA repair synthesis in human fibroblasts requires DNA polymerase delta

When UV-irradiated cultured diploid human fibroblasts were permeabilized with Brij-58 then separated from soluble material by centrifugation, conservative DNA repair synthesis could be restored by a soluble factor obtained from the supernatant of similarly treated HeLa cells. Extensive purification of this factor yielded a 10.2 S, 220,000-dalton polypeptide with the DNA polymerase and 3'- to 5'-exonuclease activities reported for DNA polymerase delta II (Crute, J. J., Wahl, A. F., and Bambara, R. A. (1986) Biochemistry 25, 26-36). Monoclonal antibody to KB cell DNA polymerase alpha, while binding to HeLa DNA polymerase alpha, did not bind to the HeLa DNA polymerase delta. Moreover, at micromolar concentrations N2-(p-n-butylphenyl)-2'-deoxyguanosine 5'-triphosphate (BuPdGTP) and 2-(p-n-butylanilino)-2'-deoxyadenosine 5'-triphosphate (BuAdATP) were potent inhibitors of DNA polymerase alpha, but did not inhibit the DNA polymerase delta. Neither purified DNA polymerase alpha nor beta could promote repair DNA synthesis in the permeabilized cells. Furthermore, under conditions which inhibited purified DNA polymerase alpha by greater than 90%, neither monoclonal antibodies to DNA polymerase alpha, BuPdGTP, nor BuAdATP was able to inhibit significantly the DNA repair synthesis mediated by the DNA polymerase delta. Thus, it appears that a major portion of DNA repair synthesis induced by UV irradiation might be catalyzed by DNA polymerase delta. When xeroderma pigmentosum human diploid fibroblasts were utilized, DNA repair synthesis dependent upon ultraviolet light could be restored by addition of both T4 endonuclease V and DNA polymerase delta, but not by addition of either one alone. This result suggests that cytosol-depleted permeabilized DNA repair-defective human fibroblasts and HeLa DNA polymerase delta might be exploited to provide a functional assay for purifying active DNA repair factors from DNA repair-proficient cells without a preknowledge of their function.     

Effect of caffeine on DNA synthesis in irradiated and unirradiated mammalian cells

Caffeine increased the availability of replication origins, and consequently the number of growing points, in the DNA of Chinese hamster V79 and human (HeLa) cells. Caffeine also prevented the inhibition of replicon initiation normally caused by X-radiation and exposure to low doses of ultraviolet light. When caffeine was removed from the medium after irradiation, replicon initiation was inhibited. Caffeine also reversed the inhibition of replicon initiation caused by novobiocin, which is not a DNA-damaging agent. Because caffeine increases the number of growing points, it also partially reversed the inhibition of total DNA synthesis induced by hydroxyurea. It is proposed that caffeine alters the conformation of intracellular chromatin in such a way that the conformation usually induced by DNA-damaging agents is prevented.     

Genotoxic effects of paracetamol in V79 Chinese hamster cells

Paracetamol was studied for possible genotoxic effects in V79 Chinese hamster cells. Paracetamol (0.5 mM for 30 min) reduced the rate of DNA synthesis in exponentially growing V79 cells to about 50% of control. A further decrease in the DNA synthesis was seen during the first 30 min after termination of paracetamol exposure. Paracetamol (3 and 10 mM for 2 h) caused a small increase in DNA single-strand breaks, as measured by the alkaline elution technique. After 16 h elution, the amount of DNA retained on the filters was 79 and 70% of controls in cells treated with 3 and 10 mM paracetamol respectively. No indication of DNA damage was seen in measuring the effect of paracetamol (0.25-10 mM for 2 h) on unscheduled DNA synthesis in growth-arrested cultures of V79 cells. At the highest concentrations (3 and 10 mM paracetamol), decreased unscheduled DNA synthesis was observed. Also UV-induced DNA-repair synthesis was inhibited by 3 and 10 mM paracetamol. DNA-repair synthesis was, however, inhibited at a much higher concentration than that inhibiting replicative DNA synthesis. The number of sister-chromatid exchanges (SCE) increased in a dose-dependent manner on 2 h exposure to paracetamol from 1 mM to 10 mM. At the highest dose tested (10 mM), the number of SCE increased to 3 times the control value. Co-culturing the V79 cells with freshly isolated mouse hepatocytes had no further effect on the paracetamol induced sister-chromatid exchanges. The present study indicates that paracetamol may cause DNA damage in V79 cells without any external metabolic activation system added.     

Clastogenicity of low pH to various cultured mammalian cells.

It has been reported that low pH itself can be clastogenic to Chinese hamster ovary cells or mouse lymphoma L5178Y cells. On the other hand, there was no indication that low pH is clastogenic to rat or human lymphocytes. Therefore, in order to evaluate the generality of clastogenicity of low pH conditions, chromosomal aberration tests were carried out on Chinese hamster cell line cells (CHO-K1, CHL, Don and V79 379A) and human cells (HeLa and peripheral lymphocytes used as whole-blood cultures). The cytotoxicity of low pH to each cell line was also evaluated by counting surviving cells. The treatment medium used was Eagle's MEM containing 15 mM MES or Bis-Tris as an organic buffer to maintain the acidity of the medium for the 6-h or 24-h treatment period, and pH adjustment was done with NaOH or HCl. Chromosomal aberrations were induced at pH 6.5 or below in CHO or CHL cells, and the maximum frequency was 24.7% at pH 6.0 or 34% at pH 6.3, respectively. About 5-10% of Don or HeLa cells had aberrations over the range of pH 6.6-6.0 or pH 6.6-6.3, respectively. In V79 379A cells or human lymphocytes, however, aberrant cells amounted to about 8% at near pH 6.0, where cell survival was low (less than 20%). About 90% of aberrations induced in each cell line examined were chromatid-type gaps and breaks. When CHO or CHL cells were treated with acidic medium for 6 h plus 18 h recovery in fresh medium, about 20% of cells had aberrations including chromatid exchanges at pH 5.5 or pH 5.7, respectively. These results indicate that clastogenicity of low pH is a general finding, although the extent of it varies with cell type, and that the clastogenicity is associated with varying extents of cytotoxicity. The mechanisms of clastogenesis at low pH are not known, but might involve inhibition of DNA or protein synthesis or DNA-repair enzymes.     

Semi-conservative synthesis of DNA in UV-sensitive mutant cells of Chinese hamster after UV-irradiation

A study was made of the rate of semi-conservative DNA synthesis in asynchronous UV-resistant (clone V79) and UV-sensitive clones (VII and XII) of Chinese hamster cells after UV-irradiation. In all 3 clones studied, UV-irradiation (5-30 J/m2) induced a decrease in the rate of DNA synthesis during the subsequent 1-2 h. In the resistant clone (V79) recovery of DNA synthesis rate started after the first 2 h post-irradiation (5 J/m2) and by the 3rd hour reached its maximum value, which constituted 70% of that observed in control, non-irradiated cells. The UV-sensitive mutant clones VII and XII showed no recovery in the rate of DNA synthesis during 6-7 h post-irradiation. The results obtained show that the survival of cells is correlated with the ability of DNA synthesis to recover after UV-irradiation in 3 clones studied. The observed recovery of UV-inhibited DNA synthesis in mutant clones may be due to certain defects in DNA repair.