DNA-repair kinetics and the sensitivity of cells to X-ray-induced chromosome aberrations: a mouse myeloid leukemia cell line and normal mouse bone marrow cells

The frequency of X-ray-induced chromosome aberrations in G1 ML-1 mouse myeloid leukemia cells and normal mouse bone marrow cells increased with post-irradiation incubation with the DNA-repair resynthesis inhibitor 1-beta-D-arabinofuranosylcytosine (araC), but the frequency of aberrations in the leukemic cells increased with quite a different time response compared to the normal cells. Irradiated normal mouse bone marrow cells had a rapid increase in the frequency of chromosome exchanges and deletions with increasing araC incubation time, for example, an increase was observed with 0.5 h araC incubation. In contrast, the ML-1 cells did not have a significant increase in aberrations until 1-2 h post-irradiation incubation with araC. These results suggest that the ML-1 cells, per unit time, initially undergo less repair of the X-ray-induced DNA damage that can be converted into chromosome aberrations. We previously showed that the ML-1 cells have a higher frequency of X-ray-induced chromosome aberrations compared to normal cells and the results presented here indicate that a slower rate of repair resynthesis is contributing to the increased sensitivity of the ML-1 cells.     

The nature and repair of DNA lesions that lead to chromosomal aberrations induced by ionizing radiations

Short treatment (up to 1 h) of cytosine arabinoside (araC) increases the frequencies of aberrations induced by X-rays in human lymphocytes, evaluated at the first mitosis following stimulation, or as prematurely condensed chromosomes of G₀ nuclei. Parallel biochemical experiments using nucleoid sedimentation technique, demonstrate that araC inhibits rejoining of DNA-strand breaks effectively. These results point out that X-ray-induced short-lived DNA strand breaks lead to chromosomal aberrations in human lymphocytes.     

3-Aminobenzamide does not affect X-ray-induced cytogenetic damage in G0 human lymphocytes

The inhibition of poly(ADP-ribose) polymerase by 3-aminobenzamide (3AB) has been reported to have very different effects on X-ray-induced chromosome aberrations in G0 human lymphocytes. One group of investigators observed a 2-3-fold increase in the yield of rings, dicentrics and chromosome breaks after X-irradiation and 3AB treatment, whereas another group found that 3AB had no effect on X-ray-induced chromosome aberrations. To resolve this discrepancy, we repeated the experiments as described by both groups and found no effect of 3 mM or 5 mM 3AB on the frequency of chromosome aberrations induced by either 1 Gy or 2 Gy of X-rays. Furthermore, we found no effect of 3AB on X-ray-induced aberration yields in C-banded prematurely condensed chromosome preparations from unstimulated human lymphocytes. These results indicate that poly(ADP-ribose) polymerase is not involved in the repair of cytogenetic damage in G0 human lymphocytes.     

Repair of X-ray induced DNA strand damage by isolated rat splenic lymphocytes.

Although a number of chemicals can alter DNA repair function, little is known about the effect of chronic, low dose exposure to environmental agents on DNA repair capacity. Lymphocytes provide a potential target population to study the effects of chronic exposures to low doses of toxic chemicals since they are an easily obtainable cell population. Prior to investigating the repair capacity of chemically exposed lymphocytes, the repair by chemically naive lymphocytes has been characterized. In the present study, the DNA repair capacity of isolated rat lymphocytes was characterized. The capacity of these cells to repair single-strand DNA breaks (SSB) was determined after in vitro treatments with X-rays. The effect of in vitro exposure to 3-aminobenzamide (3-AB) on DNA repair capacity was also assessed. The levels of induced SSB and their repair were determined using the alkaline elution technique. Splenic lymphocytes were isolated and placed in culture medium 18 h prior to assessment of repair capacity, but were not stimulated with mitogens. A dose-dependent increase in SSB was observed following exposure of lymphocytes to 300 or 600 rad. The rate of SSB repair was analyzed after a dose of 400 rad. Approximately 80% of the DNA strand break repair was completed within 60 min. The half-time for repair of these lesions by lymphocytes was determined to be 21.3 min. Exposure to 3-AB resulted in a decrease in the rate of repair of the X-ray-induced strand breakage. Although no SSB were detected at the end of a 1-h 3-AB treatment of non-irradiated cells, significant accumulation of SSB was observed after a 2-h treatment. The characterization of DNA repair in rat lymphocytes following in vitro exposure to X-rays will allow us to investigate the effects of chronic, in vivo toxicant exposure on the capacity of isolated lymphocytes to repair DNA damage produced by X-rays.     

Sensitivity to X-irradiation of peripheral blood lymphocytes from ageing donors

The proliferation of human blood lymphocytes from ageing donors, responding to concanavalin A, showed greater sensitivity to inhibition by X-rays than similar cells from younger donors. This increased sensitivity was associated with deficiency in repair of X-ray-induced damage to nuclear material, as measured by density in sucrose gradients, and with increased incidence of chromosomal damage following exposure of freshly isolated lymphocytes. There was also an increased frequency of spontaneous chromosomal aberrations in ageing subjects whose lymphocytes were deficient in repair of DNA damage.     

The role of short-lived DNA lesions in the production of chromosome-exchange aberrations

Human lymphocytes were treated with combined UVC radiation and X-rays or they were X-irradiated and incubated for 60–90 min in the presence of DNA-repair inhibitor ara-C. The X-ray induced chromosome exchange aberration yield was enhanced both by UVC and ara-C by approximately a factor of two in the linear (low dose) portion of the dose-response curve. The enhancement was small in the dose squared (high dose) portion where previous dose-fractionation experiments have shown that X-ray-induced lesions leading to aberrations exist for several hours. The yield of aberrations in lymphocytes incubated after irradiation in the presence of ara-C reaches a saturation level almost immediately after irradiation (5–15 min). These cytogenetic observations together with a previous finding (Holmberg and Strausmanis, 1983) give direct and indirect evidence that the enhanced aberration yield is due to short-lived DNA breaks formed immediately after X-irradiation.

Measurements on the repair kinetics of the DNA breaks induced by X-irradiation show that ara-C strongly impairs the repair of short-lived X-ray-induced DNA breaks. It was also observed that the DNA breaks generated after UVC irradiation occur almost immediately after irradiation and the level of these transient DNA breaks reaches saturation even for short incubation times. Thus, the repair of these breaks can compete with the repair of short-lived X-ray-induced DNA-breaks in combined irradiation with UVC and X-rays.

The experimental results can be explained on the assumption that X-ray-induced aberrations originate from exchange complexes formed in interactions between both short-lived DNA breaks. The short-lived DNA breaks give rise to exchange complexes mainly within single ionization tracks where the DNA breaks are close together. The time between irradiation and exchange complex formation is of the order of 5–15 min within such a track, and short-lived breaks might be repaired before complexes have been formed. If the DNA repair of these breaks is delayed by UVC or ara-C treatment this results in a higher probability of exchange-complex formation. In contrast, interactions between breaks in different tracks originate from long-lived DNA breaks and the probability for complex formation from these breaks is not markedly affected by UVC or ara-C.     

The effect of 3-aminobenzamide on X-ray induction of chromosome aberrations in Down syndrome lymphocytes

Human lymphocytes from normal and Down syndrome (DS) subjects were examined to determine the effect of 3-aminobenzamide (3AB) on X-ray-induced chromosome aberrations. Lymphocytes were treated with 150 or 300 rad of X-rays in the presence of 3 mM 3AB for various times after irradiation, and then the cells were analyzed for the presence of chromosome aberrations in mitotic cells. 3-Aminobenzamide had no effect on the frequency of chromosome aberrations produced by X-rays in G0 lymphocytes from normal subjects. In contrast, lymphocytes from DS patients displayed an increase in the frequency of chromosome aberrations as a result of treatment with X-rays in the presence of 3AB. These observations indicate that DS lymphocytes are more sensitive to the inhibition of poly(ADP)ribose synthetase than normal lymphocytes.     

Effect of low-dose acute X-irradiation on the frequencies of chromosomal aberrations in human peripheral lymphocytes in vitro

In a coordinated research programme sponsored by the International Atomic Energy Agency, the frequencies of chromosomal aberrations induced in peripheral blood lymphocytes (in vitro) by 250 kV X-rays at low doses (0.4, 1, 2, 3, 5, 10 and 30 rad) were determined. Blood from 2 donors was used to conduct one master experiment at these dose levels. The culture time used was 48 h and all samples including the controls were processed according to a standard protocol. The coded slides were scored by investigators from 10 participating laboratories. The main results are the following: (1) the frequencies of all types of chromosome aberrations at 0.4 rad are significantly lower than the control values; (2) there is no increase in the frequencies of dicentrics up to 2 rad and in those of terminal deletions up to 5 rad; (3) the mean frequencies of all aberrations considered together are not significantly different from one another at 1, 2 and 3 rad (P = 0.05); and (4) over the entire dose range the dose-effect relationship is clearly non-linear. A fit of these data to a linear quadratic model (E(D) = c + alpha D + beta D2) showed that the observed total aberration frequencies at doses 1, 2, 3 and 5 rad are below the curve defined by the model. The deviations can be explained by an altered kinetics of aberration production at very low doses probably due to DNA repair mechanisms operating these cells.     

Modulation of restriction enzyme-induced damage by chemicals that interfere with cellular responses to DNA damage: a cytogenetic and pulsed-field gel analysis

The electroporation of restriction enzymes into mammalian cells results in DNA double-strand breaks that can lead to chromosome aberrations. Four chemicals known to interfere with cellular responses to DNA damage were investigated for their effects on chromosome aberrations induced by AluI and Sau3AI; in addition, the number of DNA double-strand breaks at various times after enzyme treatment was determined by pulsed-field gel electrophoresis (PFGE). The poly(ADP-ribose) polymerase inhibitor 3-aminobenzamide (3AB) dramatically increased the yield of exchanges and deletions and caused a small but transitory increase in the yield of double-strand breaks induced by the enzymes. 1-beta-D-Arabinofuranosylcytosine, which can inhibit DNA repair either by direct action on DNA polymerases alpha and delta or by incorporation into DNA, potentiated aberration induction but to a lesser extent than 3AB and did not affect the amount of DNA double-strand breakage. Aphidicolin, which inhibits polymerases alpha and delta, had no effect on AluI-induced aberrations but did increase the aberration yield induced by Sau3AI. The postreplication repair inhibitor caffeine had no effect on aberration yields induced by either enzyme. Neither aphidicolin nor caffeine modulated the amount of DNA double-strand breakage as measured by PFGE. These data implicate poly(ADP-ribosyl)ation and polymerases alpha and delta as important components of the cellular processes required for the normal repair of DNA double-strand breaks with blunt or cohesive ends. Comparison of these data with the effect of inhibitors on the frequency of X-ray-induced aberrations leads us to the conclusion that X-ray-induced aberrations can result from the misjoining or nonrejoining of double-strand breaks, particularly breaks with cohesive ends, but that this process accounts for only a portion of the induced aberrations.     

Chromosome-type exchange aberrations are induced by inhibiting repair of UVC-induced DNA lesions in quiescent human lymphocytes

Human lymphocytes in the quiescent stage were UVC-irradiated and then incubated for 90 min in the presence of the DNA-repair inhibitor ara-C. The cells were then cultured and analyzed for chromosome aberrations. A single treatment with UVC or ara-C gives rise to a very low yield of dicentrics, whereas the combined treatment can induce a high frequency of these chromosome-type aberrations. The yield in the combined treatment is approximately proportional to the square of the UVC fluence in the range 1-3 J/m2. In addition, the experiments demonstrate that synergistic effects arise when cells are treated with UVC + ara-C and then exposed to X-rays. The results can be explained on the assumption that the UVC + ara-C treatment induces DNA double-strand breaks which, to the first approximation, are randomly distributed over the chromosomes. These breaks are able to interact with each other as well as with X-ray-induced DNA double-strand breaks to form a chromosome-type exchange aberration.     

On the time course of the interactions between DNA breaks in the production of a radiation-induced chromosome exchange aberration

Quiescent human lymphocytes were X-irradiated and allowed to repair for various times at 37 degrees C before the cells were challenged with the DNA-repair inhibitor ara-C. The observed yield of chromosome exchange aberrations (dicentrics) was about twice the yield induced by X-rays alone, if ara-C was added immediately after irradiation. The yield as a function of the repair time between X-irradiation and ara-C treatment decreased with a half-life of 15-30 min and was almost down to the baseline yield for X-rays alone after 1 h. This shows that an exchange aberration can be formed from a short-lived DNA break. In contrast, previously published results from dose-split experiments demonstrate that the half-life of the interacting DNA breaks is of the order of several hours. A model is proposed which can account for the different estimates of the time course of the interactions involved in the process which leads to an exchange aberration.     

Human lymphocytes exposed to low doses of ionizing radiations become refractory to high doses of radiation as well as to chemical mutagens that induce double-strand breaks in DNA

Human lymphocytes exposed to low doses of ionizing radiation from incorporated tritiated thymidine or from X-rays become less susceptible to the induction of chromatid breaks by high doses of X-rays. This response can be induced by 0.01 Gy (1 rad) of X-rays, and has been attributed to the induction of a repair mechanism that causes the restitution of X-ray-induced chromosome breaks. Because the major lesions responsible for the induction of chromosome breakage are double-strand breaks in DNA, attempts have been made to see if the repair mechanism can affect various types of clastogenic lesions induced in DNA by chemical mutagens and carcinogens. When cells exposed to 0.01 Gy of X-rays or to low doses of tritiated thymidine were subsequently challenged with high doses of tritiated thymidine or bleomycin, which can induce double-strand breaks in DNA, or mitomycin C, which can induce cross-links in DNA, approximately half as many chromatid breaks were induced as expected. When, on the other hand, the cells were challenged with the alkylating agent methyl methanesulfonate (MMS), which can produce single-strand breaks in DNA, approximately twice as much damage was found as was induced by MMS alone. The results indicate that prior exposure to 0.01 Gy of X-rays reduces the number of chromosome breaks induced by double-strand breaks, and perhaps even by cross-links, in DNA, but has the opposite effect on breaks induced by the alkylating agent MMS. The results also show that the induced repair mechanism is different from that observed in the adaptive response that follows exposure to low doses of alkylating agents.     

A calmodulin antagonist has no effect on the repair of X-ray-induced damage in a murine mammary carcinoma cell line

The effects of the calmodulin antagonist W13 were determined on potentially lethal damage repair, sublethal damage repair, and X-ray-induced DNA damage repair following X irradiation of 67 murine mammary carcinoma cells in the proliferative and quiescent states. Studies with W13 (20 micrograms/ml) on proliferating cells showed that the cells rounded up within 2 h but stayed attached to the dishes and there was a slight transient G2 block by 6 h. Also, the proportion of S-phase cells at 12 h was reduced to 65% of control with the concurrent [3H]thymidine incorporation reduced to 62% of control. There was no detectable effect from this pharmacological dose of W13 either on PLDR in proliferating cells at 400 and 800 rad or on quiescent cells at 200 and 400 rad. Likewise, there was no measurable effect on SLDR in either proliferating or quiescent cells at equally split doses of 800 and 600 rad, respectively. In addition, for control vs W13-treated proliferating cells, no difference was detected either in the induction of DNA damage by X irradiation or in the initial rate of repair (T 1/2 approximately equal to 7 min), as measured by the alkaline filter elution assay. In contrast to uv and bleomycin-induced damage, these data suggest that calmodulin may have no major role in either the molecular or cellular recovery from X-ray-induced damage in mammalian cells.     

Chromosome aberration yields in human lymphocytes induced by fractionated doses of x-radiation.

Unstimulated (G0) human peripheral blood lymphocytes were exposed at 37 degrees C to doses of 200 or 500 rad of X-rays delivered in two equal fractions. The dose fractions were separated by intervals of up to 7 h in the 200 rad study and up to 48 h for 500 rad. In both studies the mean levels of dicentrics and total unstable aberrations began to decline when fractions were delivered with intervals of greater than 2 h. With 200 rad the yield had decreased to an additive baseline (i.e. equal to only twice the yield of a single 100-rad fraction) by an interval of 4 h. Following 500 rad the yield declined until 8 h and then remained 20% above the additive baseline even when 48 h separated the fractions. Possible explanations for this discrepancy are discussed. In a second experiment PHA stimulated lymphocyte cultures were exposed to 2 doses of 125 rad of X-rays up to 7 h apart in an attempt to demonstrate the late peak in aberration yields originally reported by Lane [5]. Control cultures received unsplit doses of 250 rad at the time of the corresponding second 125-rad fraction. No evidence of a late peak in dicentric yield was observed. The yield remained approximately the same irrespective of the time interval between fractions but these split dose yields were significantly different from the accompanying unsplit controls.     

The repair of chromosome aberrations in human lymphocytes after combined irradiation with UV-radiation (254 nm) and X-rays

Human lymphocytes were exposed to UV-radiation and X-rays. The previously reported synergistic effect on the frequency of chromosome aberrations (Holmberg and Jonasson, 1974) was measured as a function of the time between the 2 irradiations to study the effect of repair processes in cells in PBS at 20 degrees C. The synergistic effect was found to be rather constant as a function of time (in the interval up to 90 min) when the UV-radiation is delivered first. The synergistic effect decreases with a half-life of about 20 min when the cells are first X-irradiated and after various times are given a UV-treatment. This is not in accordance with findings from dose-fractionation experiments with X-rays, in which lesions interact with each other for several hours. It is proposed that the enhanced aberration frequency in the combined irradiations originates from interactions between short-lived, X-ray-induced DNA-lesions in close spatial proximity (mainly lesions in the same ionization track), and the repair of these lesions are affected by the UV-treatment. In contrast, the aberrations studied in dose-fractionation experiments, by definition, are due to interactions between (long-lived) lesions in different tracks. Further details of this model for aberration production are discussed.     

The synergistic effect of aphidicolin on the yield of X-ray-induced chromosome aberrations throughout the cell cycle in JU56 cells

The effect of a 2-h post-treatment with aphidicolin at a dose sufficient to inhibit DNA synthesis on the yield of X-ray-induced chromosomal aberrations throughout the cell cycle was measured. Exposure to aphidicolin during and after irradiation brought about an increase in exchanges in cells irradiated in G2, in sister unions only in cells irradiated in S, and in all chromosome aberration types (fragments, sister unions, and dicentrics) in cells irradiated in G1. It is suggested that, during G1 and G2 but not during S inhibiting the repair enzyme alpha-polymerase brings about the conversion of some X-ray-induced DNA lesions to double-strand which can then take part in aberrations.     

Direct analysis of radiation-induced chromosome fragments and rings in unstimulated human peripheral blood lymphocytes by means of the premature chromosome condensation technique

Development of the procedure to stimulate peripheral blood lymphocytes has greatly facilitated the understanding of chromosome aberration formation and repair mechanisms in human cells. Yet, because radiation induces far more initial chromosome breaks than are observed as aberrations in metaphase, it has not been possible to examine the kinetics of primary chromosome breakage and rejoining with this procedure. An improved method to induce premature chromosome condensation in unstimulated lymphocytes has been used to study primary chromosome breakage, rejoining, and ring formation at various times after irradiation with up to 800 rad of X-rays. The dose-response relations for chromosome fragments analyzed immediately or 1, 2, or 24 h after exposure were found to be linear. Rapid rejoining of chromosome fragments, which takes place in the first 3 h after X-ray exposure, was not correlated with a simultaneous increase in the formation of rings. The yield of rings per cell scored 24 h after irradiation, however, increased significantly and fit a linear quadratic equation. Both chromosome fragment rejoining and ring formation were completed about 6 h after irradiation. The frequency distributions of rings among cells followed a Poisson distribution, whereas chromosome fragments were overdispersed.     

Blood lymphocyte culture system: quantitative analysis of X-ray-induced chromosome aberrations in man, muntjac and cattle

Peripheral blood lymphocytes of 3 mammalian species, man, muntjac and cattle, which have various amounts of DNA and divergent karyotypes, were exposed to 100-400 rad of X-rays, and frequencies of dicentrics and other aberrations were analysed at first post-irradiation metaphases. During experiments, various preparative or physical and biological factors that could influence the yield of chromosome aberrations were taken into account. The frequency of dicentrics scored at first post-irradiation metaphases showed best fit to both linear and quadratic dose-response curves, y = a + bD and y = bD + cD2 with a high correlation coefficient of 0.98 (P less than 0.001). The frequency of dicentrics obtained at different post-irradiation fixation times did not show significant variation, indicating a homogeneous sensitivity of peripheral lymphocytes to X-irradiation. BrdU incorporation following X-irradiation showed no increase in the frequency of chromosome aberrations. The frequency of dicentrics in man, muntjac and cattle showed a close correlation with their DNA content, but no meaningful correlation was found between the yield of dicentrics and the chromosome arm number or the nuclear volume. The ratio of dicentric yields, 1.00:0.67:1.04 obtained in man, muntjac and cattle were comparable to the ratio of their DNA contents, 1.00: 0.65: 1.07. The base-line frequency of SCEs was similar in the 3 species and no significant variation in SCE frequency was noticed even after administration of 400 rad of X-rays.     

Role of senataxin in DNA damage and telomeric stability

Ataxia with oculomotor apraxia type 2 (AOA2) is an autosomal recessive neurodegenerative disorder characterized by cerebellar ataxia and oculomotor apraxia. The gene mutated in AOA2, SETX, encodes senataxin (SETX), a putative DNA/RNA helicase. The presence of the helicase domain led us to investigate whether SETX might play a role in DNA damage repair and telomere stability. We analyzed the response of AOA2 lymphocytes and lymphoblasts after treatment with camptothecin (CPT), mitomycin C (MMC), H?O? and X-rays by cytogenetic and Q-FISH (quantitative-FISH) assays. The rate of chromosomal aberrations was normal in AOA2 cells after treatment with CPT, MMC, H?O? and X-rays. Conversely, Q-FISH analysis showed constitutively reduced telomere length in AOA2 lymphocytes, compared to age-matched controls. Furthermore, CPT- or X-ray-induced telomere shortening was more marked in AOA2 than in control cells. The partial co-localization of SETX with telomeric DNA, demonstrated by combined immunofluorescence-Q-FISH and chromatin immunoprecipitation, suggests a possible involvement of SETX in telomere stability.     

Suppressing effect of antimutagenic flavorings on chromosome aberrations induced by UV-light or X-rays in cultured Chinese hamster cells

Chromosome aberrations induced by UV-light or X-rays were suppressed by the post-treatment with antimutagenic flavorings, such as anisaldehyde, cinnamaldehyde, coumarin, and vanillin. UV- or X-ray-irradiated surviving cells increased in the presence of each flavoring. X-ray-induced breakage-type and exchange-type chromosome aberrations were suppressed by the vanillin treatment in the G1 phase of the cell cycle and a greater decrease in the number of X-ray-induced chromosome aberrations during G1 holding was observed in the presence of vanillin. Furthermore, a greater decrease in the number of X-ray-induced DNA single-strand breaks was observed in the presence of vanillin. Treatment with vanillin in the G2 phase suppressed UV- and X-ray-induced breakage-type but not exchange-type chromosome aberrations. The suppression of breakage-type aberrations was assumed to be due to a modification of the capability of the post-replicational repair of DNA double-strand breaks. These G1- and G2-dependent anticlastogenic effects were not observed in the presence of 2',3'-dideoxythymidine, an inhibitor of DNA polymerase beta. Based on these results, the anticlastogenic effect of vanillin was considered to be due to the promotion of the DNA rejoining process in which DNA polymerase beta acts.