DNA damage in cells exposed to ionizing radiation

Ionizing radiation induces variety of structural lesions in DNA of irradiated organisms. Their formation depends largely on the degree of cell oxygenation, the level of endogenous antioxidants, on DNA-protein complexes and compactization of DNA in the chromatin and activity of DNA repair systems. All ionizing radiation-induced DNA lesions can arbitrarily be divided into two groups. Group 1 includes singly damaged sites (single-sites): base modification, single-strand breaks, alkaline-labile sites (including a basic sites). Group 2 contains: locally multiply damaged sites (clustered lesions), double-strand breaks, intermolecular cross-links. The yields of lesions of group 2 increases with high linear energy transfer of radiation and these lesions play a dominant role in the radiation death, formation of chromosome and gene mutations, cell transformation.     

DNA damage caused by ionizing radiation in embryonic diploid fibroblasts WI-38 induces both apoptosis and senescence

Cellular response to ionizing radiation-induced damage depends on the cell type and the ability to repair DNA damage. Some types of cells undergo apoptosis, whereas others induce a permanent cell cycle arrest and do not proliferate. Our study demonstrates two types of response of embryonic diploid fibroblasts WI-38 to ionizing radiation. In the WI-38 cells p53 is activated, protein p21 increases, but the cells are arrested in G2 phase of cell cycle. Some of the cells die by apoptosis, but in remaining viable cells p16 increases, senescence associated DNA-damage foci occur, and senescence-associated beta-galactosidase activity increases, which indicate stress-induced premature senescence.     

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.     

Repair of ionizing radiation induced DNA damage in human lymphocytes.

Phytohemagglutinin stimulated human lymphocytes exhibit a 20 fold increase in DNA repair synthesis following ionizing radiation damage compared to the level of repair in unstimulated cells. The peak of repair synthesis coincides with that for DNA replication. Stimulated lymphocytes provide a relatively simple assay for ionizing radiation repair defects.     

Antioxidative effects of melatonin in protection against cellular damage caused by ionizing radiation

Ionizing radiation is classified as a potent carcinogen, and its injury to living cells is, to a large extent, due to oxidative stress. The molecule most often reported to be damaged by ionizing radiation is DNA. Hydroxyl radicals (*OH), considered the most damaging of all free radicals generated in organisms, are often responsible for DNA damage caused by ionizing radiation. Melatonin, N-acetyl-5-methoxytryptamine, is a well-known antioxidant that protects DNA, lipids, and proteins from free-radical damage. The indoleamine manifests its antioxidative properties by stimulating the activities of antioxidant enzymes and scavenging free radicals directly or indirectly. Among known antioxidants, melatonin is a highly effective scavenger of *OH. Melatonin is distributed ubiquitously in organisms and, as far as is known, in all cellular compartments, and it quickly passes through all biological membranes. The protective effects of melatonin against oxidative stress caused by ionizing radiation have been documented in in vitro and in vivo studies in different species and in in vitro experiments that used human tissues, as well as when melatonin was given to humans and then tissues collected and subjected to ionizing radiation. The radioprotective effects of melatonin against cellular damage caused by oxidative stress and its low toxicity make this molecule a potential supplement in the treatment or co-treatment in situations where the effects of ionizing radiation are to be minimized.     

Immunochemical determination of DNA damage induced by high doses of ionizing radiation

It was shown by the immunochemical method that DNA of X-irradiated E. coli cells of a radiosensitive mutant ABA88uvr A6 can react with the antiserum to thymine dimers which, in all appearance, are induced by ionizing radiation in bacterial DNA. The number of thymine dimers in DNA of E. coli AB1886uvr A6 increased with the dose increase. No dimers were detected in radioresistant cells of M. radioproteolyticus probably due to the effective excision thereof.     

Hyperthermic inactivation of diploid yeast and the interaction of damage caused by hyperthermia and ionizing radiation.

Inactivation of diploid yeast by hyperthermia has been studied. DO and Dq decrease with temperature for euoxic and anoxic conditions. The Arrhenius plot shows a break at 52 degrees C; the inactivation energies above and below this temperature are 153 and 94kcal/mol respectively. Hyperthermia (20 min at 51 degrees C) also potentiates the lethal action of gamma rays in diploid yeast cells under both euoxic and anoxic conditions. The interaction between hyperthermic and radiation damage appears to be largely at the sublethal level. The euoxic cells, the hyperthermic potentiation decreases with increasing time between the application of hyperthermia and radiation, being completely lost after 24 hours. However, in the anoxic cells there was no decrease in the hyperthermic potentiation with increasing time interval. These results suggest that yeast cells are capable of repairing hyperthermic sublethal damage, but require oxygen to do so. Thus there is a similarity in the process of repair of sublethal damage caused by ionizing radiation on the one hand and hyperthermia on the other.     

Membrane oxidative damage induced by ionizing radiation detected by fluorescence polarization

Effects of ionizing radiation on biological membranes include alterations in membrane proteins, peroxidation of unsaturated lipids accompanied by perturbations of the lipid bilayer polarity. We have measured radiation-induced membrane modifications using two fluorescent lipophilic membrane probes (TMA-DPH and DPH) by the technique of fluorescence polarization on two different cell lines (Chinese hamster ovary CHO-K1 and lymphoblastic RPMI 1788 cell lines). γ-Irradiation was performed using a ⁶⁰Co source with dose rates of 0.1 and 1 Gy/min for final doses of 4 and 8 Gy. Irradiation induced a decrease of fluorescence intensity and anisotropy of DPH and TMA-DPH in both cell lines, which was dose-dependent but varied inversely with the dose rate. Moreover, the fluorescence anisotropy measured in lymphoblastic cells using TMA-DPH was found to decrease as early as 1 h after irradiation, and remained significantly lower 24 h after irradiation. This study indicates that some alterations of membrane fluidity are observed after low irradiation doses and for some time thereafter. The changes in membrane fluidity might reflect oxidative damage, thus confirming a radiation-induced fluidization of biological membranes. The use of membrane fluidity changes as a potential biological indicator of radiation injury is discussed. Received: 14 May 1996 / Accepted in revised form: 30 September 1996     

Photoreactivation of damage induced by ionizing radiation in yeast cells

Summary Experimental data on photoreactivation of damage induced by ionizing radiation in yeast cells are presented. The value of photoreactivation was found to be the highest for the following conditions predicted by us as optimum ones: large volume of irradiated suspension, hypoxia and high energy sparsely ionizing radiation. A comparison of data for yeast and bacterial cells shows that Cerenkov emission from ionizing radiation may produce photoreactivated pyrimidine dimers in both prokaryotic and eukaryotic cell systems.     

Reparable and irreparable damage in yeast cells induced by sparsely ionizing radiation.

It is shown that in diploid yeast there are significant differences in the extent of irreparable damage after irradiation with X-rays, 60Co-gamma-rays and 30 MeV electrons. At extremely low dose rates, 60Co-gamma-rays were found to produce almost no irreparable damage at least up to 1200 Gy. X-rays, however, at the same low dose rate caused irreparable damage in the same dose range yielding a surviving fraction of 0.25 at 1200 Gy. For irradiations at high dose rate followed by liquid holding recovery the relative biological effectiveness of X-rays amounted to at least 4 for absorbed doses of up to 1000 Gy. With 30 MeV electrons at high dose rates an accumulation of sublethal and potentially lethal damage resulting in irreparable damage occurred above 1000 Gy. It is suggested that irreparable damage in yeast is due to a cooperative effect of neighbouring track ends.     

Inhibition of mammalian cell DNA synthesis by ionizing radiation

A semi-log plot of the inhibitory effect of ionizing radiation on the rate of DNA synthesis in normal mammalian cells yields a two-component curve. The steep component, at low doses, has a D0 of about 5 Gy and is the result of blocks to initiation of DNA replicons. The shallow component, at high doses, has a D0 of greater than or equal to 100 Gy and is the result of blocks to DNA chain elongation. The target size for the inhibition of DNA replicon initiation is about 1000 kb, and the target size for inhibition of DNA chain elongation is about 50 kb. There is evidence that the target for both components is DNA alone. Therefore, the target size for inhibition of DNA chain elongation is consistent with the idea that an effective radiation-induced lesion in front of the DNA growing point somehow blocks its advance. The target size for inhibition of DNA replicon initiation is so large that it must include many replicons, which is consistent with the concept that a single lesion anywhere within a large group (cluster) of replicons is sufficient to block the initiation of replication of all replicons within that cluster. Studies with radiosensitive human cell mutants suggest that there is an intermediary factor whose normal function is necessary for radiation-induced lesions to cause the inhibition of replicon initiation in clusters and to block chain elongation; this factor is not related to poly(ADP-ribose) synthesis. Studies with radiosensitive Chinese hamster cell mutants suggest that double-strand breaks and their repair are important in regulating the duration of radiation-induced inhibition of replicon initiation but have little to do with effects on chain elongation. There is no simple correlation between inhibition of DNA synthesis and cell killing by ionizing radiation.     

Thymine lesions produced by ionizing radiation in double-stranded DNA

A DNA glycosylase which catalyzes the release of thymine residues damaged by ring saturation, fragmentation, or ring contraction from double-stranded DNA has been used to characterize such base derivatives in gamma-irradiated DNA. It is shown by chromatographic analysis that irradiation of DNA in neutral solution generates the ring-saturated forms cis-thymine glycol, trans-thymine glycol, and a monohydroxydihydrothymine, probably 6-hydroxy-5,6-dihydrothymine. The latter compound is only observed after irradiation under hypoxic conditions. The ring-contracted thymine derivative 5-hydroxy-5-methylhydantoin is also formed, and it is the major lesion after irradiation of DNA under O2. Ring-fragmented products such as methyltartronylurea were only generated in small quantities. Isolation and analysis of the DNA from gamma-irradiated human cells also revealed the formation of ring-saturated thymine derivatives, but 5-hydroxy-5-methylhydantoin was not found in this case.     

In vivo interactions between ionizing radiation, inflammation and chemical carcinogens identified by increased DNA damage responses

Exposure to ionizing radiation or a variety of chemical agents is known to increase the risk of developing malignancy and many tumors have been linked to inflammatory processes. In most studies, the potentially harmful effects of ionizing radiation or other agents are considered in isolation, mainly due to the large number of experiments required to assess the effects of mixed exposures with different doses and different schedules, and the length of time and expense of studies using disease as the measure of outcome. Here, we have used short-term DNA damage responses to identify interactive effects of mixed exposures. The data demonstrate that exposure to ionizing radiation on two separate occasions ten days apart leads to an increase in the percentage of cells with a sub-G(0) DNA content compared to cells exposed only once, and this is a greater than additive effect. Short-term measurements of p53 stabilization, induction of p21/Cdkn1a and of apoptosis also identify these interactive effects. We also demonstrate similar interactive effects of radiation with the mutagenic chemical methyl-nitrosourea and with a nonspecific pro-inflammatory agent, lipopolysaccharide. The magnitude of the interactive effects is greater in cells taken from mice first exposed as juveniles compared to adults. These data indicate that short-term measurements of DNA damage and response to damage are useful for the identification of interactions between ionizing radiation and other agents.     

Quantitative detection of DNA damage in cells after exposure to ionizing radiation by means of an improved immunochemical assay.

A simple, sensitive and fast immunochemical method has been developed to quantify the amount of DNA damage in cells of human blood after in vitro exposure to ionizing radiation. The technique is based on the enhancement of the radiation-induced single-strandedness, which occurs in DNA regions flanking strand breaks, by a controlled further unwinding of the DNA in an alkaline solution. Subsequently, the DNA is attached to the wall of polystryene cups by passive adsorption. DNA damage is then quantified by determining the extent of single-strandedness with a monoclonal antibody, D1B, directed against single-stranded DNA. D1B binding is assayed with a 'second' antibody, labelled with either an enzyme or europium. The latter gives slightly more reproducible results. No radioactive labelling of DNA is required and the assay takes only 3.5 h after the collection of blood. Damage can be detected after doses as low as 0.5 Gy. The potential broader application of the method is discussed.