The effects of ionizing radiation on structure and function of DNA

Detection of DNA single-strand breaks and glutathione in mononuclear blood cells of radiotherapy technicians

We wanted to investigate the effects of gamma radiation on DNA single-strand breaks (SSB) and glutathione (GSH) levels in mononuclear blood cells (MNC) of radiotherapy technicians. DNA SSB in MNC of radiotherapy technicians who use (60)Co-gamma source in their works were detected by alkaline filter elution and compared to control subjects. In addition, GSH levels were measured using the enzymatic method in MNC. Blood samples were collected from radiotherapy technicians on Monday and Friday. DNA SSB levels were found to be significantly higher in smoking controls compared to non-smoking controls. Significant increases of 36% and 49% in DNA SSB were detected from Monday to Friday for non-smoking and smoking radiotherapy technicians, respectively. GSH levels were found to be decreased significantly from Monday to Friday. Gamma-radiation resulted in increased DNA SSB levels of MNC in radiotherapy technicians throughout the working week and these breaks have been observed to be repaired at the weekend. Smoking habit caused an additional increase in the SSBs observed in radiotherapy technicians.

Oxidative cell membrane alteration. Evidence for surfactant-mediated sealing

Exposure to very intense ionizing irradiation produces acute tissue sequelae including inflammation, pain, and swelling that often results in tissue fibrosis and/or necrosis. Acute tissue necrosis occurs in hours when sufficiently rapid damage to membrane lipids and proteins leads to altered membrane structure, disrupting the vital electrochemical diffusion barrier necessary for cell survival. This damage mechanism is thought to underlie the interphase death of lethally irradiated postmitotic cells such as neurons, but it has also been implicated in the rapid cell death of lymphocytes and acute vascular changes due to capillary epithelium dysfunction. It is not known whether sealing of radiation-permeabilized cell membranes will prolong survival of lethally irradiated cells or perhaps lead to repair of damaged nucleic acids. The purpose of this study is to begin to address the first question.

Structure of a duplex DNA containing a thymine glycol residue in solution

Oxidative stress, ionizing radiation, and other events can induce the oxidation of the thymine in DNA to thymine glycol. The presence of thymine glycol can have significant biological consequences, and there are specific repair enzymes for thymine glycol in a wide range of organisms. The structure of a duplex DNA containing a single thymine glycol (5,6-dihydroxy-5,6-dihydrothymidine) has been determined by the combined use of NMR and restrained molecular dynamics. The duplex of d(C1G2C3G4A5Tg6A7C8G9C10C11) paired with d(G22C21G20C19T18A17T16G15C14G13G12), with Tg indicating thymine glycol, has been used for these studies. The structure shows that the thymine glycol induces a significant, localized structural change with the thymine glycol largely extrahelical. This structural information is consistent with the biological consequences of thymine glycol in DNA. This structure is compared with that of a DNA duplex with an abasic site in the same sequence context.

3'-end processing and kinetics of 5'-end joining during retroviral integration in vivo

Retroviral replication depends on integration of viral DNA into a host cell chromosome. Integration proceeds in three steps: 3'-end processing, the endonucleolytic removal of the two terminal nucleotides from each 3' end of the viral DNA; strand transfer, the joining of the 3' ends of viral DNA to host DNA; and 5'-end joining (or gap repair), the joining of the 5' ends of viral DNA to host DNA. The 5'-end joining step has never been investigated, either for retroviral integration or for any other transposition process. We have developed an assay for 5'-end joining in vivo and have examined the kinetics of 5'-end joining for Moloney murine leukemia virus (MLV). The interval between 3'-end and 5'-end joining is estimated to be less than 1 h. This assay will be a useful tool for examining whether viral or host components mediate 5'-end joining. MLV integrates its DNA only after its host cell has completed mitosis. We show that the extent of 3'-end processing is the same in unsynchronized and aphidicolin-arrested cells. 3'-end processing therefore does not depend on mitosis.

Radiation induced DNA damage and damage repair in three human tumour cell lines

Three human tumour cell lines (HX142, RT112 and MGH-U1) with different radiosensitivities were tested for differences in the rate and/or extent of DNA unwinding in alkali as well as for differences in the induction of DNA double strand breaks by means of the pulsed field gel electrophoresis, after X-irradiation. Unlike that which has been found using the non-denaturing filter elution technique (NDE, McMillan et al., 1990), no differences in initial DNA damage (the extent of alkaline unwinding and the induction of double strand breaks) were found for the three cell lines. These data suggest that rather than a different number of DNA lesions per Da per Gy between these cell lines, structural differences in chromatin structure (related to radiosensitivity) might impair the detectability of lesions in some assays like the NDE. The nature of such structure differences remains unclear. However, the differences did not affect alkaline unwinding profiles, as all three cell lines showed identical rates of DNA unwinding after exposure to X-rays. Furthermore, the three cell lines did not show significant differences in the kinetics of DNA strand break rejoining nor in the amounts of damage remaining after 24 h repair. The results obtained in this study, together with other findings, suggest that the three cell lines may differ in their 'presentation' of DNA damage.

Asymmetric fusion between protoplasts of tomato (Lycopersicon esculentum Mill.) and gamma-irradiated protoplasts of potato (Solanum tuberosum L.): the effects of gamma irradiation

This paper describes the aggregation of nuclei in heterokaryons of tomato and unirradiated or irradiated potato protoplasts and the effects of gamma irradiation of potato and tomato protoplasts on single- and double-stranded DNA fragmentation, DNA repair and DNA synthesis as revealed by alkaline and pulsed field gel electrophoresis and an immunocytochemical technique. The prospects for obtaining highly asymmetric somatic hybrids of tomato and gamma-irradiated potato are discussed.

Bone marrow clastogenicity of trimethyltin

Aqueous solutions of trimethyltin in four different concentrations were administered i.p. for three different treatment periods, to five Swiss albino male mice for each experimental set. Bone marrow cells were processed for somatic chromosome preparation after 6, 18 and 24 h following the usual protocol. Structural abnormalities including chromatid and chromosome breaks, dicentrics, rings and fragments were recorded. Critical assessment of the data with the one-tailed trend test revealed a significant positive trend of the dose effects in all three treatment periods. With the ANOVA test, significant variations in aberrations were observed between chemical concentrations and between treatment periods and their interaction (dose x time) was significant in aberrations and mitotic indices. Depression of mitotic index was dose- and duration-dependent.

Response of fibroblast cultures from ataxia-telangiectasia patients to reactive oxygen species generated during inflammatory reactions

Cells from patients with ataxia-telangiectasia (AT) are more sensitive than cells from normal individuals to a number of compounds which induce DNA damage via oxygen-derived free radical attack. We tested the hypothesis that AT cells would show a sensitivity to reactive oxygen species (ROS) generated by activated inflammatory cells. AT cells were exposed to neutrophils activated with 12-O-tetradecanoyl-phorbol-13-acetate (TPA) or to xanthine/xanthine oxidase (X/XO), an enzyme system which generates superoxide and hydrogen peroxide. Induced micronuclei (MN) frequencies (corrected for spontaneous MN frequencies) were significantly higher in AT cell cultures than in cultures from normal individuals (comparison of MN frequencies of AT vs. normal cultures: for treatment with activated neutrophils, P = 0.003; for X/XO, P = 0.05). The comet assay was used to determine whether the elevated chromosomal damage in the treated AT cells was due to a difference in strand breakage or its rejoining. X/XO treatment was used in studies of single-stranded (SS) DNA breakage, and X-ray treatment for double-stranded (DS) DNA damage. AT and normal cells showed no significant differences in the initial levels of SS (P = 0.29) or DS (P = 0.91) DNA damage. Likewise, they exhibited similar rejoining kinetics (rejoining half-time for SS = 10 min, for DS = 30 min). These data support the involvement of the AT loci in determining a cell's ability to deal with oxidative stress, although the mechanism underlying this effect has yet to be resolved. The data also suggest that AT patients are at elevated risk of sustaining DNA damage in tissues undergoing inflammatory reactions.

Update on target theory as applied to chromosomal aberrations

The early radiobiologists, who developed target theory to explain their results, considered the chromosome "target" as a visible thread that could be physically broken by ionizing radiation. Most of the broken ends restituted, but those that did not were free to wander about and, within limits, could rejoin with any other broken end they happened to contact to form structural aberrations. Failing this, they could remain to be seen as "open" breaks at the subsequent metaphase. These ideas, and their inevitable consequences, still form the basis for much modern thinking, even though we now known that the structure of the chromosome, and of the interphase nucleus, are very much more complicated than the originators of the theory envisaged. Current understanding of chromosomes at the molecular level and the varied responses a cell can mobilize when damage is introduced, raise again the question, Can we still think in terms of simple targets? Some of the experimental observations and suggestions made since those early days are reviewed, and the application of target theory to the three theories of aberration origins (Classic, Exchange, Recombination) is briefly discussed.

Chromosome aberrations reduced in whole-body irradiated mice by pretreatment with cyanide

Male mice exposed to single, whole-body 60Co irradiation, were injected intraperitoneally with a non-toxic dose of KCN, 2 min or 20 min prior to irradiation. Bone-marrow cells were examined for chromatid breaks and chromosome aberrations (CA) at different times post-irradiation. The 2 min but not the 20 min treated mice had a marked reduction in chromatid breaks and chromosome aberrations. A study was made of mice exposed to 3.0 Gy (1.8 Gy/min), treated with KCN 2 min prior to irradiation and examined 5 min to 30 d post-irradiation. After 5 min there were no significant changes in frequency of CA. Subsequently, the incidence of CA in the KCN-treated group was reduced compared to the irradiated controls. By the 30th day, however, CA frequencies had returned to control levels in all groups. No effect of KCN treatment was observed in the white or red blood cells. The cytogenetic results were posited to be a function of the relative inhibition and recovery times of cyanide affected cytochrome oxidase, DNA synthesis, and ATP.

Influence of proliferation on DNA repair rates in liver

To test the hypothesis that the proliferative status of a mammalian cell determines the rate of removal of oxidative DNA damage, pre- and posthepatectomized livers in adult male Fisher 344 rats were irradiated in situ with 15.5 Gy of 137Cs-gamma-rays. At 10 and 45 min after irradiation, the livers were removed and dissociated into single cell suspensions, and the DNA damage in the isolated quiescent or proliferative liver cells was assayed by alkaline elution. Proliferative liver cells irradiated 20-24 h or 29-31 h after hepatectomy repaired their DNA damage faster than quiescent liver cells. A corresponding increase in the accessibility of the DNA to digestion by m. nuclease was observed for the post-hepatectomized liver cells. These data suggest that proliferative status is a major determinant of the rate of DNA repair in rat liver.

The ESTRO Breur lecture. Cellular sensitivity to low dose-rate irradiation focuses the problem of tumour radioresistance

This paper emphasises the radiobiology of human tumour cells irradiated at the relatively low dose rate of 1 Gy/h (i.e.1-2 cGy/min), described here as the "Regaud dose rate". Continuous irradiation at this dose rate is approximately isoeffective with fractionated radiotherapy using 2 Gy/fractions. At the Regaud dose rate, cell survival curves are approximately exponential and they appear to extrapolate the initial slope of the high dose rate survival curve. Little recovery occurs after such treatments since it has largely taken place during irradiation. At the Regaud dose rate human tumour cell lines show a wide range of radiosensitivities, differing by a factor of around 7. This may well be the most clinically-relevant way of describing the radiosensitivity of tumour cells. Current models of radiation cell killing envisage a component of damage that increases linearly with dose. It is this component that dominates the slope of the Regaud survival curve. It may be produced by DNA damage due to clusters of ionisation events, or perhaps by damage to hypersensitive parts of the genome. The steepness of this component of damage may be modified by exogenous inhibitors of DNA damage repair.

Organization of DNA in cerebellar neurons of ageing unirradiated and irradiated rats

Male Fischer 344 rats were either unirradiated or whole-brain irradiated with single doses of 10.83 or 17.16 Gy of X-rays at 4 months of age, and the organization of the DNA in permanently non-dividing cerebellar neurons examined as a function of age, dose and time after irradiation. In unirradiated rats and rats receiving a whole-brain dose of 10.83 Gy, there were no statistically significant changes in the organization of the bulk DNA and its association with the nuclear matrix as determined by: (a) the sensitivity of the DNA to digestion by micrococcal nuclease, (b) the sensitivity of the nuclear matrix-associated DNA to digestion by DNase I, (c) the relative DNA and protein content of undigested neuronal nuclei, and (d) the relative amount of DNA and protein that is tightly associated with the nuclear matrix after digestion with DNase I. In rats that were irradiated with 17.16 Gy at 4 months of age, there was a gradual decrease in the amount of nuclear proteins as a function of age (P less than 0.003). The amount of protein associated with the nuclear matrix in these irradiated aging rats was also consistently lower than that of their unirradiated counterparts (P less than 0.03). This decrease in the nuclear protein content of the cerebellar neurons in aging rats irradiated with 17.16 Gy may have caused a change in the overall organization of their neuronal DNA. Such a change in the organization of their neuronal DNA was indicated by a higher stainability of their bulk DNA by propidium iodide (P less than 0.03) and a higher sensitivity of the bulk DNA to digestion by m. nuclease (P = 0.087). Although these organizational changes in the neuronal DNA of aging rats irradiated with 17.16 Gy at 4 months of age are subtle, they might alter DNA repair processes or other neuronal functions that may be associated with the "natural" process of aging.

Nuclear lysate sedimentation measurements of peripheral blood lymphocytes from radiotherapy patients

When isolated nuclei of human lymphocytes are challenged with 2 M NaCl a histone-free-DNA-protein (HF-DNA) complex is released. In a linear sucrose gradient (pH 8.0) the sedimentation distance of HF-DNA is reduced when immediately isolated from cells irradiated in vitro. At low doses, if irradiated cells are incubated at 37 degrees C the sedimentation behaviour approaches that of unirradiated cells (i.e. repair). In the present study such repair was usually complete within 1 h. The radiation damage to lymphocytes from a healthy donor group and three patient groups consisting of new patients (before radiotherapy), well patients (2 to 6 years post-radiotherapy) and patients with complications attributed to radiotherapy was similar. The lymphocytes from most healthy donors and new patients demonstrated complete repair of radiation damage following an incubation of 1 h at 37 degrees C. However, 2/29 (6.9 per cent) healthy donors and 2/25 (8 per cent) new patients demonstrated poor repair. Of those patients now attending with 'bowel complications' attributed to radiotherapy 7/16 (44 per cent) demonstrated poor repair. In contrast, all those (11/11) described as 'well and complication-free' showed good repair.

The role of repair in radiobiology

Apart from cancer and mutation induction, radiobiological effects on mammals are mostly attributable to cell 'death', defined as loss of proliferative capacity. Survival curves relate retention of that capacity to radiation dose, and often manifest a quasi-threshold ('shoulder'). The shoulder is attributable to an initial mechanism of repair ('Q-repair') which is gradually depleted as dose increases. Another form of repair, which is not depleted ('P-repair'), increases the dose required to deliver an average of one lethal event per cell (dose 'D0'). Neither form of repair can unambiguously be linked with repair of defects in isolated DNA. An important initial lesion may well be disruption of the complex structural relationship between the DNA, nuclear membrane and associated proteins. One form of P-repair may be restoration of that structural relationship.

Effects of tert-butyl hydroperoxide on promotable and non-promotable JB6 mouse epidermal cells

Oxidants and agents that induce a cellular prooxidant state can act as carcinogens. We compared the effect of tert-butyl hydroperoxide (Bu-OOH) on DNA strand breakage, poly ADP-ribosylation of chromosomal proteins and the expression of the proto-oncogenes c-fos and c-myc between non-promotable clone 30 and promotable clone 41 of mouse epidermal cells JB6. These pathophysiological effects of oxidants are mechanistically related. Bu--OOH caused more DNA-strand breakage at high concentrations and more extensive poly ADP-ribose accumulation in clone 30 than in clone 41, in reactions which require intracellular free iron. Clone 41 exhibited constitutive c-myc expression while c-fos mRNA was very low in untreated cultures of both clones. Low concentrations of Bu-OOH induced c-myc and more strongly c-fos in clone 41. Both proto-oncogenes were strongly induced in clone 30. Our results allow insights into the mechanisms of action of a typical organic hydroperoxide in JB6 cells. However, they do not uncover the reasons for the differential promotability of the two JB6 clones by oxidants beyond the implication of the constitutive expression of c-myc in promotable clone 41.