Effect of intercellular contact on DNA conformation, radiation-induced DNA damage, and mutation in Chinese hamster V79 cells

Chinese hamster V79 cells, when grown as small spheroids in suspension culture, are more resistant to killing by ionizing radiation than when grown as monolayers. We have attempted to determine whether this enhanced survival following irradiation is reflected in DNA damage and repair at the structural level (by measuring alkali-induced DNA unwinding rates from strand breaks) and at the functional level (by measuring resistance to forward mutation at the HGPRT locus). For a given dose of radiation, the unwinding of DNA in high salt/weak alkali was less complete for spheroid DNA than for monolayer DNA, and the rate of repair of radiation damage was faster in spheroid DNA. These differential responses were lost 8 hr after separation of spheroids into single cells, coinciding with loss of radioresistance measured by clonogenicity. In addition, spheroid cells showed fewer numbers of induced mutants per Gray, although, for a given level of survival, the mutation frequency for monolayers and spheroids was identical. These results suggest that conformational changes in DNA resulting from cell growth as spheroids might enhance repair of radiation-induced lesions.     

Differences in Phosphorylated Histone H2AX Foci Formation and Removal of Cells Exposed to Low and High Linear Energy Transfer Radiation

The use of particle ion beams in cancer radiotherapy has a long history. Today, beams of protons or heavy ions, predominantly carbon ions, can be accelerated to precisely calculated energies which can be accurately targeted to tumors. This particle therapy works by damaging the DNA of tissue cells, ultimately causing their death. Among the different types of DNA lesions, the formation of DNA double strand breaks is considered to be the most relevant of deleterious damages of ionizing radiation in cells. It is well-known that the extremely large localized energy deposition can lead to complex types of DNA double strand breaks. These effects can lead to cell death, mutations, genomic instability, or carcinogenesis. Complex double strand breaks can increase the probability of mis-rejoining by NHEJ. As a consequence differences in the repair kinetics following high and low LET irradiation qualities are attributed mainly to quantitative differences in their contributions of the fast and slow repair component. In general, there is a higher contribution of the slow component of DNA double strand repair after exposure to high LET radiation, which is thought to reflect the increased amount of complex DNA double strand breaks. These can be accurately measured by the γ-H2AX assay, because the number of phosphorylated H2AX foci correlates well with the number of double strand breaks induced by low or / and high LET radiation.     

Chemical radiosensitization by misonidazole: production and repair of DNA single-strand breaks in Yoshida ascites tumor cells.

Formation of strand-breaks in DNA and its repair in Yoshida ascites tumor cells exposed to gamma radiation (100-400 Gy) in presence and absence of misonidazole (10 mM) were studied. The methodology involved pre-labelling of cellular DNA by 3H-thymidine during cell proliferation in rats, irradiation of cells in vitro and analysing sedimentation profile of DNA by ultracentrifugation in alkaline sucrose density gradients. Irradiation under euoxic conditions resulted in formation of about 1.5 times greater number of strand breaks as compared to those formed during irradiation under hypoxic conditions. Misonidazole (10 mM) by its presence along with the cells during irradiation under hypoxic conditions caused a 3-fold increase in the number of single strand breaks, but under euoxic conditions of irradiation the presence of misonidazole did not enhance the strand break formation. Incubation of cells irradiated in absence of misonidazole for 1 hr in tissue culture medium at 37 degrees C resulted in repair of substantial fraction of the strand breaks while there was no repair of the DNA strand breaks in cells irradiated in the presence of the chemical.     

Hyperthermic potentiation of unrejoined DNA strand breaks following irradiation

Previous reports have suggested that the potentiation of cellular radiation sensitivity by hyperthermia may be due to its inhibition of the repair of single-strand breaks in DNA. Such inhibition could result in increased numbers of unrejoined breaks at long times following irradiation, lesions that are presumed to be lethal to the cell. As a test of this hypothesis, the amounts of residual strand-break damage in cells following combined hyperthermia and ionizing radiation were measured. The results show that hyperthermia does significantly enhance the relative number of unrejoined strand breaks as measured by the technique of alkaline elution and that the degree of enhancement is dependent on both the temperature and duration of the hyperthermia treatment. For example, compared to unheated cells, the proportion of unrejoined breaks measured 8 hr after irradiation was increased by a factor of 1.5 in cells that were treated for 30 min at 43 degrees C, by a factor of 6 for cells treated for 30 min at 45 degrees C, and by a factor of 4 for cells treated at 43 degrees C for 2 hr. In experiments in which the sequence of heat and irradiation were varied, a high degree of correlation was observed between the resulting level of cell killing and the relative numbers of unrejoined strand breaks. The greatest effects on both of these parameters were observed in those protocols in which the irradiation was delivered either during, just before, or just after the heat treatment.     

Changes of 8-OH-dG levels in DNA and its base excision repair activity in rat lungs after inhalation exposure to hexavalent chromium

The co-genotoxic effects of cadmium are well recognized and it is assumed that most of these effects are due to the inhibition of DNA repair. We used the comet assay to analyze the effect of low, non-toxic concentrations of CdCl2 on DNA damage and repair-induced in Chinese hamster ovary (CHO) cells by UV-radiation, by methyl methanesulfonate (MMS) and by N-methyl-N-nitrosourea (MNU). The UV-induced DNA lesions revealed by the comet assay are single-strand breaks which are the intermediates formed during nucleotide excision repair (NER). In cells exposed to UV-irradiation alone the formation of DNA strand breaks was rapid, followed by a fast rejoining phase during the first 60 min after irradiation. In UV-irradiated cells pre-exposed to CdCl2, the formation of DNA strand breaks was significantly slower, indicating that cadmium inhibited DNA damage recognition and/or excision. Methyl methanesulfonate and N-methyl-N-nitrosourea directly alkylate nitrogen and oxygen atoms of DNA bases. The lesions revealed by the comet assay are mainly breaks at apurinic/apyrimidinic (AP) sites and breaks formed as intermediates during base excision repair (BER). In MMS treated cells the initial level of DNA strand breaks did not change during the first hour of recovery; thereafter repair was detected. In cells pre-exposed to CdCl2 the MMS-induced DNA strand breaks accumulated during the first 2h of recovery, indicating that AP sites and/or DNA strand breaks were formed but that further steps of BER were blocked. In MNU treated cells the maximal level of DNA strand breaks was detected immediately after the treatment and the breaks were repaired rapidly. In CdCl2 pre-treated cells the formation of MNU-induced DNA single-strand breaks was not affected, while the repair was slower, indicating inhibition of polymerization and/or the ligation step of BER. Cadmium thus affects the repair of UV-, MMS- and MNU-induced DNA damage, providing further evidence, that inhibition of DNA repair is an important mechanism of cadmium induced mutagenicity and carcinogenicity.     

Defective repair of DNA single- and double-strand breaks in the bleomycin- and X-ray-sensitive Chinese hamster ovary cell mutant, BLM-2

Using filter elution techniques, we have measured the level of induced single- and double-strand DNA breaks and the rate of strand break rejoining following exposure of two Chinese hamster ovary (CHO) cell mutants to bleomycin or neocarzinostatin. These mutants, designated BLM-1 and BLM-2, were isolated on the basis of hypersensitivity to bleomycin and are cross-sensitive to a range of other free radical-generating agents, but exhibit enhanced resistance to neocarzinostatin. A 1-h exposure to equimolar doses of bleomycin induces a similar level of DNA strand breaks in parental CHO-K1 and mutant BLM-1 cells, but a consistently higher level is accumulated by BLM-2 cells. The rate of rejoining of bleomycin-induced single- and double-strand DNA breaks is slower in BLM-2 cells than in CHO-K1 cells. BLM-1 cells show normal strand break repair kinetics. The level of single- and double-strand breaks induced by neocarzinostatin is lower in both BLM-1 and BLM-2 cells than in CHO-K1 cells. The rate of repair of neocarzinostatin-induced strand breaks is normal in BLM-1 cells but retarded somewhat in BLM-2 cells. Thus, there is a correlation between the level of drug-induced DNA damage in BLM-2 cells and the bleomycin-sensitive, neocarzinostatin resistant phenotype of this mutant. Strand breaks induced by both of these agents are also repaired with reduced efficiency by BLM-2 cells. The neocarzinostatin resistance of BLM-1 cells appears to be a consequence of a reduced accumulation of DNA damage. However, the bleomycin-sensitive phenotype of BLM-1 cells does not apparently correlate with any alteration in DNA strand break induction or repair, as analysed by filter elution techniques, suggesting an alternative mechanism of cell killing.     

Assessment of radiation-induced DNA strand breaks and their repair in unlabeled cells.

Radiation induced damage, i.e., the induction of DNA strand breaks, was studied on the level of single, unlabeled cells. DNA strand breaks were determined by direct partial alkaline unwinding in intact cell nuclei followed by staining with acridine orange, a development of a proposal first described by B. Rydberg (Int J Radiat Biol 46:521-527, 1984). The ratio of green fluorescence (double-stranded DNA) to red fluorescence (single-stranded DNA) in single cells was taken as a measure of DNA strand breaks. CHO-K1 and M3-1 cells irradiated with X-rays show a dose dependent induction of DNA strand breaks. Incubation at 37 degrees C after irradiation leads to repair of breaks. A repair halflife of about 10-11 min can be determined. Cell cycle specific differences in the induction of DNA strand breaks or repair behavior are not detectable at the resolution achieved so far. This new method offers two major advantages: the resolution of DNA damage and repair on the level of single cells and no need for labeling, thereby allowing for DNA damage and repair to be assessed in biopsy material from tumor patients.     

The occurrence of DNA strand breaks after hyperthermic treatments of mammalian cells with and without radiation

Strand breaks were detected in the DNA of Ehrlich ascites cells as well as in HeLa S3 cells directly after 1-5 hr at 43-45 degrees C by the use of the unwinding in high salt/hydroxylapatite method. The strand breaks found could not be attributed to the decay of incorporated tritiated thymidine. When the cells were incubated at 37 degrees C after the hyperthermic treatments, the amount of strand breaks formed remained at a constant level. Hyperthermia inhibited the repair of "radiation-induced" strand breaks. The repair curves obtained this way show a heat-dose-dependent decrease of the relative weight of the fast component of repair. Similar repair curves of "radiation-induced" strand breaks could be obtained by mixing heat inactivated and vital control cells prior to irradiation. In the latter case, however, the DNA repair was inhibited to a greater extent for identical levels of cell survival. The possible underlying molecular mechanisms are discussed.     

Quantitative measurement of DNA strand breaks and repair in gamma-irradiated human leukocytes from normal and ataxia telangiectasia donors

Fluorimetric analysis of DNA unwinding, which allows measurement of DNA strand breaks in human leukocytes, has been optimized by reducing the amount of cells required for the test and by modifying the DNA alkali unwinding conditions. This permitted measurement of DNA strand-break induction in cells irradiated with low (0.5-7 Gy) or high doses (5-20 Gy) of gamma rays. Linear dose-response curves were obtained for both dose ranges. Presence of cysteamine during irradiation caused a decrease in the extent of DNA strand breaks. The kinetics of the DNA strand-break rejoining process appeared to be biphasic over the dose range of 2-20 Gy when plotted on a linear vs linear axis (percentage of damage as a function of time). Since the rate of disappearance of damaged DNA was similar for any given dose and for all postirradiation incubation times tested, we have expressed the extent of repair after a given postirradiation incubation as the ratio of the slopes of the regression lines obtained from incubated and nonincubated cells. Leukocytes from 25 healthy donors were analyzed to determine an average value for controls. No difference in the level of DNA strand breaks and the rate of repair of these breaks was observed between leukocytes from three ataxia telangiectasia patients and those from normal donors.     

Detection and repair of a UV-induced photosensitive lesion in the DNA of human cells

Irradiation with UV light results in damage to the DNA of human cells. The most numerous lesions are pyrimidine dimers; however, other lesions are known to occur and may contribute to the overall deleterious effect of UV irradiation. We have observed evidence of a UV-induced lesion other than pyrimidine dimers in the DNA of human cells by measuring DNA strand breaks induced by irradiating with 313-nm light following UV (254-nm) irradiation. These breaks, measured by alkaline sucrose sedimentation, increased linearly with the dose of UV light over the range tested (10-40 J/m2). The breaks cannot be photolytically induced 5 h after a UV dose of 20 J/m2 in normal cells; however, in xeroderma pigmentosum variant cells, the breaks are inducible for up to 24 h after UV irradiation. Xeroderma pigmentosum group A cells in the same 5-h period show an increase in the number of strand breaks seen with 313-nm light photolysis from about 2 to 4 breaks/10(9) dalton DNA. These breaks can then be induced for up to 24 h. These data suggest that, in normal cells, the lesion responsible for this effect is rapidly repaired or altered; whereas, in xeroderma pigmentosum variant cells it seems to remain unchanged. Some change apparently occurs in the DNA of xeroderma pigmentosum group A cells which results in an increase in photolability. These data indicate a deficiency in DNA repair of xeroderma pigmentosum variant cells as well as in xeroderma pigmentosum group A cells.     

DNA repair kinetics in irradiated undifferentiated and terminally differentiated cells

The brains of male Fisher 344 rats bearing 80-150 mg intracerebral 9L/Ro tumors were irradiated with doses of 1,250-5,000 rads of x- or gamma-rays. At various times after irradiation, the cerebellum and tumor were excised, dissociated into single cells and the DNA from these cells sedimented through alkaline sucrose gradients in zonal rotors with slow gradient reorienting capability. Quantitation of the DNA repair kinetics demonstrated that the process in both tumor cells and neurons has a fast and slow phase. Although all other alternatives cannot be completely eliminated, we suggest that these two phases are most reasonably interpreted as representing repair of lesions in very accessible and less accessible regions of the genome rather than 1) repair of different types of lesions such as single- or double-strand breaks or 2) removal of immediate breaks and breaks induced during excision repair of latent base damage. The slow repair phase is saturable, but not inducible in both tumor cells and neurons. The data suggest that tumor cells restore their chromosomal DNA structure to the unirradiated state faster than neurons because 1) they contain more of the repair system per unit of DNA and 2) a larger proportion of their genetic material is comprised of very accessible regions. The data also suggest that the entire tumor cell genome may be accessible to the repair enzyme(s), while it is possible that a portion of the neuronal genome may be completely inaccessible.     

Role of oxidative stress and DNA damage in human carcinogenesis

Cells in tissues and organs are continuously subjected to oxidative stress and free radicals on a daily basis. This free radical attack has exogenous or endogenous (intracellular) origin. The cells withstand and counteract this occurrence by the use of several and different defense mechanisms ranging from free radical scavengers like glutathione (GSH), vitamins C and E and antioxidant enzymes like catalase, superoxide dismutase and various peroxidases to sophisticated and elaborate DNA repair mechanisms. The outcome of this dynamic equilibrium is usually the induction of oxidatively induced DNA damage and a variety of lesions of small to high importance and dangerous for the cell i.e. isolated base lesions or single strand breaks (SSBs) to complex lesions like double strand breaks (DSBs) and other non-DSB oxidatively generated clustered DNA lesions (OCDLs). The accumulation of DNA damage through misrepair or incomplete repair may lead to mutagenesis and consequently transformation particularly if combined with a deficient apoptotic pathway. In this review, we present the current status of knowledge and evidence on the mechanisms and involvement of intracellular oxidative stress and DNA damage in human malignancy evolution and possible use of these parameters as cancer biomarkers. At the same time, we discuss controversies related to potential artifacts inherent to specific methodologies used for the measurement of oxidatively induced DNA lesions in human cells or tissues.     

Biochemical and cytogenetical characterization of Chinese hamster ovary X-ray-sensitive mutant cells xrs 5 and xrs 6. VI. The correlation between UV-induced DNA lesions and chromosomal aberrations, and their modulations with inhibitors of DNA repair synthesis

The role of UV-induced DNA lesions and their repair in the formation of chromosomal aberrations in the xrs mutant cell lines xrs 5 and xrs 6 and their wild-type counterpart, CHO-K1 cells, were studied. The extent of induction of DNA single-strand breaks (SSBs) and DNA double-strand breaks (DSBs) due to UV irradiation in the presence or absence of 1-beta-D-arabinofuranosylcytosine (ara-C) and hydroxyurea (HU) was determined using the alkaline and neutral elution methods. Results of these experiments were compared with the frequencies of induced chromosomal aberrations in UV-irradiated G1 cells treated under similar conditions. Xrs 6 cells showed a defect in their ability to perform the incision step of nucleotide repair after UV irradiation. Accumulation of breaks 2 h after UV irradiation in xrs 6 cells in the presence of HU and ara-C remained at the level of incision breaks estimated after 20 min, which was about 35% of that found in wild-type CHO-K1 cells. In UV-irradiated CHO-K1 and xrs 5 cells, more incision breaks were present after 2 h compared with 20 min post-treatment with ara-C, a further increase was evident when HU was added to the combined treatment. The level of incision breaks induced under these conditions in xrs 5 was about 80% of that observed in CHO-K1 cells. UV irradiation itself did not induce any detectable DNA strand breaks. Accumulation of SSBs in UV-irradiated cells post-treated with ara-C and HU coincides with the increase in the frequency of chromosomal aberrations. These data suggest that accumulated SSBs when converted to DSBs in G1 give rise to chromosome-type aberrations, whereas strand breaks persisting until S-phase result in chromatid-type aberrations. Xrs 6 appeared to be the first ionizing-radiation-sensitive mutant with a partial defect in the incision step of DNA repair of UV-induced damage.     

Repair Replication and Degradation of Bromouracil-Substituted DNA in Mammalian Cells after Irradiation with Ultraviolet Light

Ultraviolet (UV) light irradiation of HeLa cells in which bromouracil (BU) is substituted for thymine in one strand of the DNA, elicits a number of responses that occur predominantly in the BU strand. A small amount of degradation of both strands occurs, but the BU strand is degraded to a greater extent than the normal strand. Large UV doses (1000 erg/mm²) induce degradation of about 1.7% of the DNA within 6 hr of irradiation of unsubstituted cells; in BU-substituted cells under these conditions about 1.9% of the normal strand is degraded but 17.5% of the BU strand. After irradiation fresh bases are inserted into the BU strands at infrequent intervals throughout the DNA and this is presumed to represent repair of UV damage in the BU strands. After 1000 erg/mm² the majority (70%) of the thymidine incorporated enters the BU strand. Inhibitors of normal DNA synthesis, hydroxyurea and arabinosyl cytosine, do not appear to inhibit the repair of DNA. The increased sensitivity of mammalian cells that contain BU to irradiation may consequently be due to damage of the BU strand. A specific interference between BU and repair of DNA which leads to large amounts of DNA degradation in bacteria, does not seem to be important in the sensitization of mammalian cells with BU.     

Clusters of S1 nuclease-hypersensitive sites induced in vivo by DNA damage.

DNA end-labeling procedures were used to analyze both the frequency and distribution of DNA strand breaks in mammalian cells exposed or not to different types of DNA-damaging agents. The 3' ends were labeled by T4 DNA polymerase-catalyzed nucleotide exchange carried out in the absence or presence of Escherichia coli endonuclease IV to cleave abasic sites and remove 3' blocking groups. Using this sensitive assay, we show that DNA isolated from human cells or mouse tissues contains variable basal levels of DNA strand interruptions which are associated with normal bioprocesses, including DNA replication and repair. On the other hand, distinct dose-dependent patterns of DNA damage were assessed quantitatively in cultured human cells exposed briefly to menadione, methylmethane sulfonate, topoisomerase II inhibitors, or gamma rays. In vivo induction of single-strand breaks and abasic sites by methylmethane sulfonate was also measured in several mouse tissues. The genomic distribution of these lesions was investigated by DNA cleavage with the single-strand-specific S1 nuclease. Strikingly similar cleavage patterns were obtained with all DNA-damaging agents tested, indicating that the majority of S1-hypersensitive sites detected were not randomly distributed over the genome but apparently were clustered in damage-sensitive regions. The parallel disappearance of 3' ends and loss of S1-hypersensitive sites during post-gamma-irradiation repair periods indicates that these sites were rapidly repaired single-strand breaks or gaps (2- to 3-min half-life). Comparison of S1 cleavage patterns obtained with gamma-irradiated DNA and gamma-irradiated cells shows that chromatin structure was the primary determinant of the distribution of the DNA damage detected.     

Nature of DNA lesions induced in human hepatoma cells, human colonic cells and human embryonic lung fibroblasts by the antiretroviral drug 3'-azido-3'-deoxythymidine

This study tried to clarify the question if nuclear genotoxicity played a role in 3'-azido-3'-deoxythymidine (AZT) toxicity. We investigated cytotoxic and DNA-damaging effects of AZT on human hepatoma HepG2 and human colonic CaCo-2 cells as well as on human diploid lung fibroblasts HEL. The amount of induced DNA damage was measured by standard alkaline single cell gel electrophoresis (SCGE). The nature of induced DNA lesions was evaluated (1) by modified SCGE, which includes treatment of lysed cells with DNA repair enzymes Endo III and Fpg and enables to recognize oxidized bases of DNA, and (2) by SCGE processed in parallel at pH 13.0 (standard technique) and pH 12.1, which enables to recognize alkali labile DNA lesions and direct DNA strand breaks. Cytotoxicity of AZT was evaluated by the trypan blue exclusion technique. Our findings showed that 3-h treatment of cells with AZT decreased the viability of all cell lines studied. SCGE performed in the presence of DNA repair enzymes proved that AZT induced oxidative lesions to DNA in all cell types. In hepatoma HepG2 cells and embryonic lung fibroblasts HEL the majority of AZT-induced DNA strand breaks were pH-independent, i.e. they were identified at both pH values (12.1 and 13.0). These DNA lesions represented direct DNA breaks. In colonic Caco-2 cells DNA lesions were converted to DNA strand breaks particularly under strong alkaline conditions (pH>13.0), which is characteristic for alkali-labile sites of DNA. DNA strand break rejoining was investigated by the standard comet assay technique during 48 h of post-AZT-treatment in HepG2 and Caco-2 cells. The kinetics of DNA rejoining, considered an indicator of DNA repair, revealed that AZT-induced DNA breaks were repaired in both cell types slowly, though HepG2 cells seemed to be more repair proficient with respect to AZT-induced DNA lesions.     

Single strand breakage and repair in eukaryotic DNA as assayed by S1 nuclease.

A sensitive new approach for measuring the repair of single strand breaks in DNA induced by low doses of gamma irradiation was tested in cultured fibroblasts from Chinese hamster lung, human afflicted with ataxia telangiectasia or Fanconi's anemia and in normal cells of early and late passages. The assay is based on the increasing rate of strand separation of DNA duplexes in alkali for molecules with increasing numbers of single strand scissions. DNA strand separation is shown to follow the relation, in F = -(1/Mn - const) - tbeta where F is the proportion of double-stranded DNA, detected as S1 nuclease resistant, after alkaline denaturation time, t. Mn is the number-average molecular weight of DNA between single strand breaks. beta less than 1 is an empirically determined constant. The results suggest an increase in the number-average molecular weight between breaks, Mn, with increasing times for repair. The final level attained corresponds to the Mn of control DNA in unirradiated cells. As few as one break introduced into 109 daltons of single-stranded control cell DNA can be detected. The kinetics, requirements and sensitivities of this assay are described.     

Independent and sequential recruitment of NHEJ and HR factors to DNA damage sites in mammalian cells

Damage recognition by repair/checkpoint factors is the critical first step of the DNA damage response. DNA double strand breaks (DSBs) activate checkpoint signaling and are repaired by nonhomologous end-joining (NHEJ) and homologous recombination (HR) pathways. However, in vivo kinetics of the individual factor responses and the mechanism of pathway choice are not well understood. We report cell cycle and time course analyses of checkpoint activation by ataxia-telangiectasia mutated and damage site recruitment of the repair factors in response to laser-induced DSBs. We found that MRN acts as a DNA damage marker, continuously localizing at unrepaired damage sites. Damage recognition by NHEJ factors precedes that of HR factors. HR factor recruitment is not influenced by NHEJ factor assembly and occurs throughout interphase. Damage site retention of NHEJ factors is transient, whereas HR factors persist at unrepaired lesions, revealing unique roles of the two pathways in mammalian cells.     

Reduction in DNA repair capacity following differentiation of murine proadipocytes

It has been suggested that terminally differentiated mammalian cells have a decreased DNA repair capacity, compared with proliferating stem cells. To investigate this hypothesis, we have examined gamma-ray-induced DNA strand breaks and their repair in the murine proadipocyte stem cell line 3T3-T. By exposure to human plasma, 3T3-T cells can be induced to undergo nonterminal and then terminal differentiation. DNA strand breaks were evaluated using the technique of alkaline elution. No difference was detected among stem, nonterminally differentiated, and terminally differentiated cells in the initial levels of radiation-induced DNA strand breaks. Each of the strand break dose response increased as a linear function of gamma-ray dose. The strand breaks induced by 4 Gy rejoined following biphasic kinetics for each cell type. At each time point examined after irradiation, however, the percentage of strand breaks that had not rejoined in terminally differentiated cells was three to six times greater than in stem cells. The rate of strand break rejoining in nonterminally differentiated cells was of an intermediate value between that of the stem and of the terminally differentiated cells. These results indicate that, at least for 3T3-T cells, differentiated cells have a reduced capacity for DNA repair.     

Repair of radiation-induced DNA strand breaks does not occur preferentially in transcriptionally active DNA.

Certain DNA base lesions induced by ionizing radiation or oxidative stress are repaired faster from the transcribed strand of active genes compared to the genome overall. In this study, it was investigated whether radiation-induced DNA strand breaks are preferentially repaired in active genes compared to the genome as a whole in CHO cells. The alkaline unwinding technique coupled to slot-blot hybridization with specific DNA probes was used to study the induction and repair of DNA strand breaks in defined DNA sequences. Results using this technique showed a linear dose response for the formation of radiation-induced DNA strand breaks in the dihydrofolate reductase (DHFR) gene. Furthermore, the half-life of radiation-induced strand breaks was less than 5 min in the DHFR gene, in the ribosomal genes, and in the genome as a whole. These results suggest that the repair of DNA strand breaks is fast and uniform in the genome of mammalian cells.