Adaptation and impairment of DNA repair function in pollen of Betula verrucosa and seeds of Oenothera biennis from differently radionuclide-contaminated sites of Chernobyl

BACKGROUND AND AIMS: The plants that have remained in the contaminated areas around Chernobyl since 1986 encapsulate the effects of radiation. Such plants are chronically exposed to radionuclides that they have accumulated internally as well as to alpha-, beta- and gamma-emitting radionuclides from external sources and from the soil. This radiation leads to genetic damage that can be countered by DNA repair systems. The objective of this study is to follow DNA repair and adaptation in haploid cells (birch pollen) and diploid cells (seed embryos of the evening primrose) from plants that have been growing in situ in different radionuclide fall-out sites in monitored regions surrounding the Chernobyl explosion of 1986. METHODS: Radionuclide levels in soil were detected using gamma-spectroscopy and radiochemistry. DNA repair assays included measurement of unscheduled DNA synthesis, electrophoretic determination of single-strand DNA breaks and image analysis of rDNA repeats after repair intervals. Nucleosome levels were established using an ELISA kit. KEY RESULTS: Birch pollen collected in 1987 failed to perform unscheduled DNA synthesis, but pollen at gamma/beta-emitter sites has now recovered this ability. At a site with high levels of combined alpha- and gamma/beta-emitters, pollen still exhibits hidden damage, as shown by reduced unscheduled DNA synthesis and failure to repair lesions in rDNA repeats properly. Evening primrose seed embryos generated on plants at the same gamma/beta-emitter sites now show an improved DNA repair capacity and ability to germinate under abiotic stresses (salinity and accelerated ageing). Again those from combined alpha- and gamma/beta-contaminated site do not show this improvement. CONCLUSIONS: Chronic irradiation at gamma/beta-emitter sites has provided opportunities for plant cells (both pollen and embryo cells) to adapt to ionizing irradiation and other environmental stresses. This may be explained by facilitation of DNA repair function.     

DNA repair in cells of C57bl mice after radiation and in vivo treatment with a DNA site modulator of poly(ADP-ribose)-polymerase

Poly(ADP-ribose)-polymerase is an important cellular regulatory enzyme which can change chromatin structure and function. Action mechanisms and activation of the enzyme are described. The synthesis of poly(ADP-ribose) can be modulated by interaction of substances with the DNA binding site of the poly(ADP-ribose)-polymerase. The involvement of this enzyme in DNA repair, differentiation, carcinogenesis and DNA replication has been suggested. Unscheduled DNA synthesis in spleen cells of C57bl mice drug treated and gamma irradiated in vivo and 3 days later UV irradiated in vitro showed a slight decrease in grain numbers of treated animals. Poly(ADP-ribose)-synthesis was highest in the irradiated groups 18 hours after gamma irradiation. A higher amount of supercoils in DNA was generated by both drugs used. In one long-term experiment the gamma-irradiated group of mice had the highest incidence of lymphomas, while the combined treatment group, modulated and gamma irradiated, showed a lymphoma level like in the unirradiated control group.     

Age-related loss of DNA repair synthesis in isolated rat myocardial cells

Singly isolated beating heart cells from newborn rats performed unscheduled DNA synthesis (‘repair’ synthesis) when irradiated with ultraviolet light in vitro. Repair synthesis could not be induced in beating cardiac cells isolated from adult animals (3–12 months old).     

Inhibition of unscheduled DNA synthesis and repair of potentially lethal X-ray damage by 2-deoxy-D-glucose in yeast.

The effects of the glucose antimetabolite, 2-deoxy-D-glucose (2-DG), on DNA repair (assayed by unscheduled DNA synthesis) and on the repair of potentially-lethal damage (assayed by cell viability after irradiation) have been studied in X-irradiated respiratory-deficient yeast cells (auxotroph for 5'-thymidine-monophosphate). Experimental results show that: (a) both these phenomena can be inhibited by 2-DG; (b) the repair of potentially-lethal damage occurs after the unscheduled DNA synthesis is almost complete; and (c) the repair of potentially-lethal damage can be inhibited by 2-DG even after the completion of the unscheduled DNA synthesis.     

Indications of an adaptive response in C57BL mice pre-exposed in vivo to low doses of ionizing radiation

C57BL/6 mice were whole-body irradiated with 5 cGy/day (‘adapting dose’) on 4 consecutive days and their spleens removed on day 1, 3, 7, 12, 19 or 26 after the last irradiation. In vitro UV-light-induced unscheduled DNA synthesis (UDS) and mitomycin C (MMC)-induced sister-chromatid exchanges (SCEs) were scored in lymphocytes (UV-light and MMC being the ‘challenging agents’), yielding higher UDS values and lower frequencies of induced SCEs than cells of non-adapted animals. On day 12 this effect could only be seen in half, on days 19 and 26 in none of the performed experiments. The results support those published by Tuschl et al. (1980, 1983) and Liu et al. (1987), showing that it is possible to induce the adaptive response in vivo.     

Measurements of alkali-labile DNA damage and protein-DNA crosslinks after 2450 MHz microwave and low-dose gamma irradiation in vitro

In vitro experiments were performed to determine whether 2450 MHz microwave radiation induces alkali-labile DNA damage and/or DNA-protein or DNA-DNA crosslinks in C3H 10T(1/2) cells. After a 2-h exposure to either 2450 MHz continuous-wave (CW) microwaves at an SAR of 1.9 W/kg or 1 mM cisplatinum (CDDP, a positive control for DNA crosslinks), C3H 10T(1/2) cells were irradiated with 4 Gy of gamma rays ((137)Cs). Immediately after gamma irradiation, the single-cell gel electrophoresis assay was performed to detect DNA damage. For each exposure condition, one set of samples was treated with proteinase K (1 mg/ml) to remove any possible DNA-protein crosslinks. To measure DNA-protein crosslinks independent of DNA-DNA crosslinks, we quantified the proteins that were recovered with DNA after microwave exposure, using CDDP and gamma irradiation, positive controls for DNA-protein crosslinks. Ionizing radiation (4 Gy) induced significant DNA damage. However, no DNA damage could be detected after exposure to 2450 MHz CW microwaves alone. The crosslinking agent CDDP significantly reduced both the comet length and the normalized comet moment in C3H 10T(1/2) cells irradiated with 4 Gy gamma rays. In contrast, 2450 MHz microwaves did not impede the DNA migration induced by gamma rays. When control cells were treated with proteinase K, both parameters increased in the absence of any DNA damage. However, no additional effect of proteinase K was seen in samples exposed to 2450 MHz microwaves or in samples treated with the combination of microwaves and radiation. On the other hand, proteinase K treatment was ineffective in restoring any migration of the DNA in cells pretreated with CDDP and irradiated with gamma rays. When DNA-protein crosslinks were specifically measured, we found no evidence for the induction of DNA-protein crosslinks or changes in amount of the protein associated with DNA by 2450 MHz CW microwave exposure. Thus 2-h exposures to 1.9 W/ kg of 2450 MHz CW microwaves did not induce measurable alkali-labile DNA damage or DNA-DNA or DNA-protein crosslinks.     

DNA repair after gamma irradiation in lymphocytes exposed to low-frequency pulsed electromagnetic fields

The effect of exposure to extremely low-frequency pulsed electromagnetic fields (EMFs) on DNA repair capability and on cell survival in human lymphocytes damaged in vitro with gamma rays was studied by two different micromethods. In the first assay, which measures DNA repair synthesis (unscheduled DNA synthesis, UDS), lymphocyte cultures were stimulated with phytohemagglutinin (PHA) for 66 h and then treated with hydroxyurea (which blocks DNA replication), irradiated with 100 Gy of 60Co, pulsed with [3H]thymidine ([3H]TdR), and then exposed to pulsed EMFs for 6 h (the period in which cells repaired DNA damage). In the second assay, which measures cell survival after radiation or chemical damage, lymphocytes were first irradiated with graded doses of gamma rays or treated with diverse antiproliferative agents, and then stimulated with PHA, cultured for 72 h, and pulsed with [3H]TdR for the last 6 h of culture. In this case, immediately after the damage induced by either the radiation or chemicals, cultures were exposed to pulsed EMFs for 72 h, during which cell proliferation took place. Exposure to pulsed EMFs did not affect either UDS or cell survival, suggesting that this type of nonionizing radiation--to which humans may be exposed in the environment, and which is used for both diagnostic and therapeutic purposes--does not affect DNA repair mechanisms.     

Differentiated cells from BALB/c mice differ in their radiosensitivity

Various isolated cells of an inbred mouse strain (BALB/c) differed widely in their sensitivity to gamma irradiation: fibroblasts are five times more resistant than peripheral lymphocytes. Among lymphocytes, T cells are more resistant than B cells. Cell lines derived from the primary cells conserved their radiosensitivity. Cytofluorometric measurements show that the differential reaction of a cell to gamma irradiation can be detected already 2–3 h after the irradiation event. Radiation-sensitive cells are delayed for a longer time in S phase and G2 phase of the cell cycle than radiation-resistant cells. No difference in the capacity of the cells to perform single-strand break repair, double-strand break repair or unscheduled DNA synthesis could yet be detected.     

A new flow cytometric method to follow DNA gap filling during nucleotide excision repair of UVc-induced damage

BACKGROUND: Several methods have been developed for studying the kinetics of DNA repair after exposure of cells to ultraviolet (UV) light, such as conventional assays measuring unscheduled DNA synthesis (UDS). In this study, we have developed an accurate and rapid method to follow DNA gap filling during nucleotide excision repair (NER) in normal human fibroblasts (NHFs) in response to UV-induced damage. METHODS: After UVc irradiation, aphidicolin was added to the culture to hold repair patches open. This allowed an efficient incorporation of biotin-21-dUTP during an endogenous DNA repair synthesis that was detected by flow cytometry. RESULTS: We showed that the DNA gap filling after UVc irradiation in NHFs increased with time up to 10 h after irradiation and that no repair synthesis activity could be detected in XP-A fibroblasts. Furthermore, this activity was UVc dose dependent up to 20 J/m2. These results correlated well with those of the UDS assay. Interestingly, addition of aphidicolin at different time points after UVc irradiation, thus allowing endogenous repair synthesis in the absence of biotin-21-dUTP, demonstrated that the response of the NER system occurred extremely rapidly after irradiation. CONCLUSIONS: This method may be a reliable and simple alternative to other techniques measuring UDS. Practical advantages include the rapidity of the method, no need for radioactivity, and the possibility to use a second and/even a third flow marker to analyse cell cycle and heterogeneous cell populations concomitantly.     

Ultraviolet induction of prophage lambda during inhibition of deoxyribonucleic acid synthesis by hydroxyurea.

Hydroxyurea inhibited synthesis of certain deoxyribonucleic acid (DNA) precursors and causes the cessation of DNA synthesis. It did not cause induction of lambda. Superinfection of an irradiated lysogen with lambdaind- could prevent induction, but the percentage of cells protected decreased as the time between irradiation and superinfection increased. The presence of hydroxyurea did not increase the time during which cells could be rescued by superinfection. The accumulation of DNA precursors after ultraviolet or ionizing radiation was not necessary for the induction of lambda prophage to occur.     

Protection against radiation oxidative damage in mice by Triphala

Protection against whole body gamma-irradiation (WBI) of Swiss mice orally fed with Triphala (TPL), an Ayurvedic formulation, in terms of mortality of irradiated animals as well as DNA damage at cellular level has been investigated. It was found that radiation induced mortality was reduced by 60% in mice fed with TPL (1g/kg body weight/day) orally for 7 days prior to WBI at 7.5 Gy followed by post-irradiation feeding for 7 days. An increase in xanthine oxidoreductase activity and decrease in superoxide dismutase activity was observed in the intestine of mice exposed to WBI, which, however, reverted back to those levels of sham-irradiated controls, when animals were fed with TPL for 7 days prior to irradiation. These data have suggested the prevention of oxidative damage caused by whole body radiation exposure after feeding of animals with TPL. To further understand the mechanisms involved, the magnitude of DNA damage was studied by single cell gel electrophoresis (SCGE) in blood leukocytes and splenocytes obtained from either control animals or those fed with TPL for 7 days followed by irradiation. Compared to irradiated animals without administering TPL, the mean tail length was reduced about three-fold in blood leukocytes of animals fed with TPL prior to irradiation. Although, similar protection was observed in splenocytes of TPL fed animals, the magnitude of prevention of DNA damage was significantly higher than that observed in leukocytes. It has been concluded that TPL protected whole body irradiated mice and TPL induced protection was mediated through inhibition of oxidative damage in cells and organs. TPL seems to have potential to develop into a novel herbal radio-protector for practical applications.     

Physiological responses of the hyperthermophilic archaeon "Pyrococcus abyssi" to DNA damage caused by ionizing radiation

The mechanisms by which hyperthermophilic Archaea, such as "Pyrococcus abyssi" and Pyrococcus furiosus, survive high doses of ionizing gamma irradiation are not thoroughly elucidated. Following gamma-ray irradiation at 2,500 Gy, the restoration of "P. abyssi" chromosomes took place within chromosome fragmentation. DNA synthesis in irradiated "P. abyssi" cells during the DNA repair phase was inhibited in comparison to nonirradiated control cultures, suggesting that DNA damage causes a replication block in this organism. We also found evidence for transient export of damaged DNA out of irradiated "P. abyssi" cells prior to a restart of chromosomal DNA synthesis. Our cell fractionation assays further suggest that "P. abyssi" contains a highly efficient DNA repair system which is continuously ready to repair the DNA damage caused by high temperature and/or ionizing radiation.     

Unscheduled DNA synthesis induced by N-acetoxy-2-acetylaminofluorene is not sensitive to regulation by ADP-ribosyl transferase

We have directly compared in resting human mononuclear leukocytes the DNA repair effects caused by ADP-ribosyl transferase (ADPRT) activity following DNA damage induction by gamma radiation, UV radiation, ethylene oxide (EO) and N-acetoxy-2-acetylaminofluorene (NA-AAF). The presence of inhibitors of ADPRT during the quantitation of unscheduled DNA synthesis (UDS) resulted in about a 2-fold increase of UDS when induced by gamma radiation, UV radiation or EO. The stimulation of UDS by EO, UV- or gamma-radiation in the presence of an ADPRT inhibitor was equally strong whether 1 mM or 10 mM hydroxyurea was used to suppress scheduled DNA synthesis. The level of NA-AAF induced UDS was not affected by inhibitors of ADPRT. In addition, direct estimation of ADPRT activity revealed that at doses giving maximal UDS, NA-AAF damage did not induce a measurable enzymatic activity whereas gamma-radiation, UV radiation and EO all showed a significant dose response increase. We have interpreted our data to mean that NA-AAF induced UDS estimates DNA repair relating mainly to DNA lesions that are recognized with difficulty, and hence, the rate of endonuclease-induced DNA strand break accumulation is not sufficient to allow a stimulation of ADPRT and affect the quantitation of UDS.     

Induction and repair of DNA damage in gamma-irradiated human lymphoblasts: irradiation in the presence and absence of misonidazole

The effects of oxygen and misonidazole on the induction of DNA lesions were examined in human TK6 lymphoblasts irradiated with 60Co gamma rays. We have investigated both the formation and subsequent repair of two classes of DNA damage, single-strand breaks and lesions recognized by the gamma endonuclease activity in a cell-free extract of Micrococcus luteus. Relative to irradiation under hypoxia, single-strand break yields were increased by the presence of either oxygen or misonidazole at the time of irradiation. In contrast, M. luteus enzyme-sensitive site yields were unaffected by the presence of either oxygen or misonidazole. No significant differences in single-strand break or enzyme-sensitive site repair kinetics were observed for lesions induced under any of the irradiation conditions employed. These results confirm the sensitizing effects of oxygen and oxygen-mimetic drugs on the induction of single-strand breaks but provide no support for their ability to enhance the induction of enzyme-sensitive sites.     

Activation of antioxidative enzymes induced by low-dose-rate whole-body gamma irradiation: adaptive response in terms of initial DNA damage

An adaptive response induced by long-term low-dose-rate irradiation in mice was evaluated in terms of the amount of DNA damage in the spleen analyzed by a comet assay. C57BL/ 6N female mice were irradiated with 0.5 Gy of (137)Cs gamma rays at 1.2 mGy/h; thereafter, a challenge dose (0.4, 0.8 or 1.6 Gy) at a high dose rate was given. Less DNA damage was observed in the spleen cells of preirradiated mice than in those of mice that received the challenge dose only; an adaptive response in terms of DNA damage was induced by long-term low-dose-rate irradiation in mice. The gene expression of catalase and Mn-SOD was significantly increased in the spleen after 23 days of the low-dose-rate radiation (0.5 Gy). In addition, the enzymatic activity of catalase corresponded to the gene expression level; the increase in the activity was observed at day 23 (0.5 Gy). These results suggested that an enhancement of the antioxidative capacities played an important role in the reduction of initial DNA damage by low-dose-rate radiation.     

DNA damage and repair in gamma-glutamyltranspeptidase-positive and negative hepatocytes in primary culture from carcinogen-treated rats.

Chemically induced DNA fragmentation and unscheduled DNA synthesis were determined in gamma-glutamyltranspeptidase (GGT)-positive and GGT-negative hepatocytes isolated from rat livers subjected to a multistage hepatocarcinogenesis regimen (Solt-Farber), which included 0.05% phenobarbital promotion for 6 weeks (early) or 6 months (late). The results indicated that there was DNA damage in untreated GGT-positive and GGT-negative hepatocytes with either period of promotion compared with normal hepatocytes; however, no statistical difference could be seen between GGT-positive and GGT-negative hepatocytes. DNA damage induced in vitro by the activation-dependent carcinogen dimethylnitrosamine was much less in GGT-positive hepatocytes than in GGT-negative hepatocytes or normal hepatocytes. No significant difference in DNA damage was seen in both GGT-positive and GGT-negative cell populations following treatment with the activation-independent carcinogen ethylnitrosourea (ENU), although DNA damage of GGT-positive hepatocytes was less than that of normal hepatocytes. The background of unscheduled DNA synthesis in both GGT-positive and GGT-negative hepatocytes at either time of promotion was higher than that of normal hepatocytes. The capacity for DNA repair in GGT-positive hepatocytes appeared to be lower than that in GGT-negative hepatocytes. GGT-negative hepatocytes exhibited a lower capacity for DNA repair than that of normal hepatocytes in terms of the rate of unscheduled DNA synthesis elicited by dimethylnitrosamine and ethylnitrosourea in vitro.     

Relative biological effectiveness of the alpha-particle emitter (211)At for double-strand break induction in human fibroblasts

The purpose of this study was to quantify and to determine the distribution of DNA double-strand breaks (DSBs) in human cells irradiated in vitro and to evaluate the relative biological effectiveness (RBE) of the alpha-particle emitter (211)At for DSB induction. The influence of the irradiation temperature on the induction of DSBs was also investigated. Human fibroblasts were irradiated as intact cells with alpha particles from (211)At, (60)Co gamma rays and X rays. The numbers and distributions of DSBs were determined by pulsed-field gel electrophoresis with fragment analysis for separation of DNA fragments in sizes 10 kbp-5.7 Mbp. A non-random distribution was found for DSB induction after irradiation with alpha particles from (211)At, while irradiation with low-LET radiation led to more random distributions. The RBEs for DSB induction were 2.1 and 3.1 for (60)Co gamma rays and X rays as the reference radiation, respectively. In the experiments studying temperature effects, nuclear monolayers were irradiated with (211)At alpha particles or (60)Co gamma rays at 2 degrees C or 37 degrees C and intact cells were irradiated with (211)At alpha particles at the same temperatures. The dose-modifying factor (DMF(temp)) for irradiation of nuclear monolayers at 37 degrees C compared with 2 degrees C was 1.7 for (211)At alpha particles and 1.6 for (60)Co gamma rays. No temperature effect was observed for intact cells irradiated with (211)At. In conclusion, irradiation with alpha particles from (211)At induced two to three times more DSB than gamma rays and X rays.     

Measurement of the kinetics of DNA repair synthesis after uv irradiation using immunochemical staining of incorporated 5-bromo-2'-deoxyuridine and flow cytometry

The kinetics of unscheduled DNA synthesis in normal human fibroblasts was characterized by flow cytometry utilizing the immunofluorescent detection of 5-bromo-2'-deoxyuridine (BrdUrd) incorporated into cellular DNA during the repair process. Quiescent normal human fibroblasts were irradiated with ultraviolet light and incubated in the presence of BrdUrd during a postirradiation repair period. The amount of unscheduled DNA synthesis was then quantified in the quiescent cells by immunofluorescence staining using monoclonal antibodies against BrdUrd incorporated into the DNA. Significant amounts of unscheduled DNA synthesis were measured after doses as low as 0.1 J/m2 and for time periods as short as 15 min. The initial repair rate was found to be linear with time at all doses tested until repair neared completion. Interestingly, the initial repair rate was constant for doses over the range of 5 to 40 J/m2, whereas the time to completion of repair was dose dependent. These results suggest that above 5 J/m2 in normal human fibroblasts, the repair process is saturated but continues to function until all available regions are repaired. Using this methodology for measuring unscheduled DNA synthesis in combination with second and third flow markers, it is now possible to measure unscheduled DNA synthesis in heterogeneous mixtures of cells.     

Kinetics of unscheduled DNA synthesis in UV-irradiated chicken embryo fibroblasts

Unscheduled DNA synthesis induced by 254-nm UV radiation in chicken embryo fibroblasts was examined for 24 h following irradiation, while cells were kept in the dark. The effect on this repair process of a 2-4 h exposure to photoreactivating light immediately after UV was studied. Initial [3H]thymidine incorporation in the light-treated cells was only slightly different from that in cells not exposed to light, but a distinct difference in rate and cumulative amount of unscheduled DNA synthesis was seen several hours after irradiation. By varying the UV dose and the time allowed for photoreactivation, the amount of dimers (determined as sites sensitive to a M. luteus UV-endonuclease) and non-dimers could be changed. The results of these experiments suggest that excision repair of dimers, rather than non-dimer products, is responsible for the unscheduled DNA synthesis seen after UV irradiation.     

Effect of low-dose radiation on repair of DNA and chromosome damage

In this report results of studies on the effect of different doses of low LET (linear energy transfer) radiations on the unscheduled DNA synthesis (UDS) and DNA polymerase activity as well as the induction of adaptive response in bone marrow cells (BMC) by low dose radiation were presented. It was found that whole-body irradiation (WBI) with X-ray doses above 0.5 Gy caused a dose-dependent depression of both UD5 and DNA polymerase activity, while low dose radiation below 250 mGy could stimulate the DNA repair synthesis and the enzyme activity. WBI of mice with low doses of X-rays in the range of 2-100 mGy at a dose rate of 57.3 mGy per minute induced an adaptive response in the BMC expressed as a reduction of chromosome aberrations following a second exposure to a larger dose (0.65 mGy). It was demonstrated that the magnitude of the adaptive response seemed to be inversely related to the induction dose. The possibility of induction of adaptive response in GO phase of the cell cycle and the possibility of a second induction of the adaptive response were discussed.