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.     

Cellular responses to ionizing radiation: effects of interrupting DNA repair with chemical agents

This review is concerned with the influence of different classes of chemical agents on cellular repair of DNA damage induced by ionizing radiation. Single-strand break rejoining is little affected by inhibitors of DNA synthesis; however, such inhibitors do lead to a persistence of double-strand breaks in the DNA, and this correlates with an enhancement of chromosome aberrations and cell killing. Experiments with antagonists of topoisomerase II suggest an intriguing role for this DNA unwinding enzyme in double-strand break repair. Interference with poly(ADP-ribose) synthesis, by means of the inhibitor 3-aminobenzamide, does not have a clear-cut effect on recovery from ionizing radiation damage. Various substances (for example, caffeine and trypsin) affect DNA repair via a modulation of the cell cycle, altering the time available to the cell for repairing potentially lethal DNA damage before such damage is 'fixed' by the process of DNA replication. Finally, disturbing cellular energy metabolism, and depressing the level of ATP, can inhibit the repair of radiation damage.     

A new mechanism for repairing oxidative damage to DNA: (A)BC excinuclease removes AP sites and thymine glycols from DNA

Escherichia coli (A)BC excinuclease is the major enzyme responsible for removing bulky adducts, such as pyrimidine dimers and 6-4 photoproducts, from DNA. Mutants deficient in this enzyme are extremely sensitive to UV and UV-mimetic agents, but not to oxidizing agents, or ionizing radiation which damages DNA in part by generating active oxygen species. DNA glycosylases and AP1 endonucleases play major roles in repairing oxidative DNA damage, and thus it has been assumed that nucleotide excision repair has no role in cellular defense against damage by ionizing radiation and oxidative damage. In this study we show that the E. coli nucleotide excision repair enzyme (A)BC excinuclease removes from DNA the two major products of oxidative damage, thymine glycol and the baseless sugar (AP site). We conclude that nucleotide excision repair is an important cellular defense mechanism against oxidizing agents.     

DNA-protein cross-links in nuclei and mitochondria of tissue cells from rats of various age exposed to gamma-radiation

The formation and repair of DNA-protein cross-links (DPC) in the mitochondria and nuclei from the brain and spleen of 2- and 29-month rats after their exposure to ionizing radiation were studied. The background level of DPC in brain and spleen mitochondria of old rats was shown to be about two times as high as in young rats. In the nuclei from the brain of old rats the background amount of DPC was also increased, unlike the nuclei of spleen of the same rats. At the doses 5 and 10 Gy (137Cs), the amount of DPC produced in the mitochondria and nuclei of brain and spleen of 29-month rats was 1.8-2.5 times greater than in the nuclei of the same tissues of young animals. At the same time, in the mitochondria of brain and spleen from irradiated rats the amount of DPC was by 30-80% higher than in the nuclei of the same tissues. Analysis of changes in DPC content during the post-radiation period showed that 5 h after irradiation of rats with a dose of 10 Gy, the level of these lesions in the nuclei of brain and spleen of young rats decreased by 40 and 65%, respectively, whereas the amount of these lesions in the mitochondria did not decrease. In this post-radiation period in nuclei of brain and spleen of old rats the amount of DPC decreased by 20-40%, respectively. However, the data on DPC obtained for the mitochondria of brain and spleen from both young and old rats showed that the amount of these lesions did not decrease during the 5 h post-radiation period. These results enable the suggestion that mitochondria do not possess a system of DPC repair. To summarize, ionizing radiation initiates in the nuclei of brain and spleen of old rats more DPC and their repair proceeds slower than in the nuclei of the same tissues of young animals. In the mitochondria of gamma-radiation exposed old rats more DPC are also produced than in young rats but no repair of DPC is observed in both old and young animals within the 5 h post-radiation period.     

Repair of gamma-ray-induced base damage in L5178Y sublines is damage type-dependent and unrelated to radiation sensitivity.

The L5178Y (LY) murine lymphoma sublines LY-R and LY-S are differentially sensitive to ionizing radiation. The high radiation sensitivity of LY-S cells is related to impaired rejoining of DNA double strand breaks. We found previously that the gamma-ray-induced base damage is higher in the more radiosensitive LY-S subline. Here, we examine the role of the repair of ionizing radiation induced base damage in relation to the radiosensitivity difference of these sublines. We used the GS/MS technique to estimate the repair rates of six types of base damage in gamma-irradiated LY cells. All modified DNA bases identified in the course of this study were typical for irradiated chromatin. The total amount of initial base damage was higher in the radiation sensitive LY-S subline than in the radiation resistant LY-R subline. The repair rates of 5-OHMeUra, 5-OHCyt, 8-OHAde were similar in both cell lines, the repair rates of FapyAde and 8-OHGua were higher in the radiosensitive LY-S cell line, whereas the repair of 5-OHUra was faster in its radioresistant counter, the LY-R. Altogether, the repair rates of the y-ray-induced DNA base damage in LY sublines are related neither to the initial amounts of the damaged bases nor to the differential lethal or mutagenic effects of ionizing radiation in these sublines.     

Microbeam irradiation of C. elegans nematode in microfluidic channels

To perform high-throughput studies on the biological effects of ionizing radiation in vivo, we have implemented a microfluidic tool for microbeam irradiation of Caenorhabditis elegans. The device allows the immobilization of worms with minimal stress for a rapid and controlled microbeam irradiation of multiple samples in parallel. Adapted from an established design, our microfluidic clamp consists of 16 tapered channels with 10-μm-thin bottoms to ensure charged particle traversal. Worms are introduced into the microfluidic device through liquid flow between an inlet and an outlet, and the size of each microchannel guarantees that young adult worms are immobilized within minutes without the use of anesthesia. After site-specific irradiation with the microbeam, the worms can be released by reversing the flow direction in the clamp and collected for analysis of biological endpoints such as repair of radiation-induced DNA damage. For such studies, minimal sample manipulation and reduced use of drugs such as anesthetics that might interfere with normal physiological processes are preferable. By using our microfluidic device that allows simultaneous immobilization and imaging for irradiation of several whole living samples on a single clamp, here we show that 4.5-MeV proton microbeam irradiation induced DNA damage in wild-type C. elegans, as assessed by the formation of Rad51 foci that are essential for homologous repair of radiation-induced DNA damage.     

Homologous and non-homologous recombination differentially affect DNA damage repair in mice

Ionizing radiation and interstrand DNA crosslinking compounds provide important treatments against cancer due to their extreme genotoxicity for proliferating cells. Both the efficacies of such treatments and the mutagenic potential of these agents are modulated by the ability of cells to repair the inflicted DNA damage. Here we demonstrate that homologous recombination-deficient mRAD54(-/-) mice are hypersensitive to ionizing radiation at the embryonic but, unexpectedly, not at the adult stage. However, at the adult stage mRAD54 deficiency dramatically aggravates the ionizing radiation sensitivity of severe combined immune deficiency (scid) mice that are impaired in DNA double-strand break repair through DNA end-joining. In contrast, regardless of developmental stage, mRAD54(-/-) mice are hypersensitive to the interstrand DNA crosslinking compound mitomycin C. These results demonstrate that the two major DNA double-strand break repair pathways in mammals have overlapping as well as specialized roles, and that the relative contribution of these pathways towards repair of ionizing radiation-induced DNA damage changes during development of the animal.     

DNA lesions that signal the induction of radioresistance and DNA repair in yeast

DNA recombinational repair, and an increase in its capacity induced by DNA damage, is believed to be the major mechanism that confers resistance to killing by ionizing radiation in yeast. We have examined the nature of the DNA lesions generated by ionizing radiation that induce this mechanism, using two different end points: resistance to cell killing and ability of the error-free recombinational repair system to compete for other DNA lesions and thereby suppress chemical mutation. Under the various conditions examined in this study, the "maximum" inducible radiation resistance was increased approximately 1.5- to 3-fold and suppression of mutation about 10-fold. DNA lesions produced by low-LET gamma rays at doses greater than about 20 Gy given in oxygen were shown to be more efficient, per unit dose, at inducing radioresistance to killing than were lesions produced by neutrons (high-LET radiation). This suggests that DNA single-strand breaks are more important lesions in the induction of radioresistance than DNA double-strand breaks. Oxygen-modified lesions produced by gamma rays (low-LET radiation) were particularly efficient as induction signals. DNA damage due to hydroxyl radicals (OH.) derived from the radiolytic decomposition of H2O produced lesions that strongly induced this DNA repair mechanism. Similarly, OH. derived from aqueous electrons (e-aq) in the presence of N2O also efficiently induced the response. Cells induced to radioresistance to killing with high-LET radiation did not suppress N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-generated mutations as well as cells induced with low-LET radiation, supporting the conclusion that the type of DNA damage produced by low-LET radiation is a better inducer of recombinational repair. Surprisingly, however, cells induced with gamma radiation in the presence of N2O that became radioresistant to killing were unable to suppress MNNG mutations. This result indicates that OH. generated via e-aq (in N2O) may produce unusual DNA lesions which retard normal repair and render the system unavailable to compete for MNNG-generated lesions. We suggest that the repairability of these unique lesions is restricted by either their chemical nature or topological accessibility. Attempted repair of these lesions has lethal consequences and accounts for N2O radiosensitization of repair-competent but not incompetent cells. We conclude that induction of radioresistance in yeast by ionizing radiation responds variably to different DNA lesions, and these affect the availability of the induced recombinational repair system to deal with subsequent damage.     

Aging impairs double‐strand break repair by homologous recombination in Drosophila germ cells

Aging is characterized by genome instability, which contributes to cancer formation and cell lethality leading to organismal decline. The high levels of DNA double‐strand breaks (DSBs) observed in old cells and premature aging syndromes are likely a primary source of genome instability, but the underlying cause of their formation is still unclear. DSBs might result from higher levels of damage or repair defects emerging with advancing age, but repair pathways in old organisms are still poorly understood. Here, we show that premeiotic germline cells of young and old flies have distinct differences in their ability to repair DSBs by the error‐free pathway homologous recombination (HR). Repair of DSBs induced by either ionizing radiation (IR) or the endonuclease I‐SceI is markedly defective in older flies. This correlates with a remarkable reduction in HR repair measured with the DR‐white DSB repair reporter assay. Strikingly, most of this repair defect is already present at 8 days of age. Finally, HR defects correlate with increased expression of early HR components and increased recruitment of Rad51 to damage in older organisms. Thus, we propose that the defect in the HR pathway for germ cells in older flies occurs following Rad51 recruitment. These data reveal that DSB repair defects arise early in the aging process and suggest that HR deficiencies are a leading cause of genome instability in germ cells of older animals.     

The effect of aging on cell-free protein synthesis in the free-living nematode Turbatrix aceti

The age-related reduction in cell-free protein synthesis in the free-living nematode Turbatrix aceti is due to a defect in the ribosomes. Addition of young ribosomal wash or use of young medium does not improve the activity of old, run-off ribosomes in the presence of phenylalanine and poly(U). It appears that some of the old ribosomes are incapable of binding the EF-1-GTP-aminoacyl-tRNA complex. These ineffective ribosomes are present in the 80 S (monosomal) fraction. Old ribosomes obtained from polysomes appear to bind normally.     

Involvement of DNA polymerase beta in repair of ionizing radiation damage as measured by in vitro plasmid assays

Characteristic of damage introduced in DNA by ionizing radiation is the induction of a wide range of lesions. Single-strand breaks (SSBs) and base damages outnumber double-strand breaks (DSBs). If unrepaired, these lesions can lead to DSBs and increased mutagenesis. XRCC1 and DNA polymerase beta (polbeta) are thought to be critical elements in the repair of these SSBs and base damages. XRCC1-deficient cells display a radiosensitive phenotype, while proliferating polbeta-deficient cells are not more radiosensitive. We have recently shown that cells deficient in polbeta display increased radiosensitivity when confluent. In addition, cells expressing a dominant negative to polbeta have been found to be radiosensitized. Here we show that repair of radiation-induced lesions is inhibited in extracts with altered polbeta or XRCC1 status, as measured by an in vitro repair assay employing irradiated plasmid DNA. Extracts from XRCC1-deficient cells showed a dramatically reduced capacity to repair ionizing radiation-induced DNA damage. Extracts deficient in polbeta or containing a dominant negative to polbeta also showed reduced repair of radiation-induced SSBs. Irradiated repaired plasmid DNA showed increased incorporation of radioactive nucleotides, indicating use of an alternative long-patch repair pathway. These data show a deficiency in repair of ionizing radiation damage in extracts from cells deficient or altered in polbeta activity, implying that increased radiosensitivity resulted from radiation damage repair deficiencies.     

Induced repair of DNA double-strand breaks at the G1/S-phase border

Exposure of human cells to ionizing radiation at the G1/S-phase border of the cell cycle leads to the production of repair patches of 3 nucleotides, representing the constitutive repair response, and very long repair patches (VLRP) of at least 150 nucleotides, representing an induced response. We examined the type of DNA damage that may signal this induced repair response using two chemicals that produce subsets of the damage induced by ionizing radiation. Treatment of cells at the G1/S-phase border with bleomycin, which produces a high proportion of DNA double-strand breaks, also leads to the production of VLRP of at least 130 nucleotides. In contrast, when cells were treated with hydrogen peroxide, which produces base modifications and single-strand breaks, no VLRP were observed. Thus it would appear that DNA double-strand breaks are the signal that leads to the induction of the VLRP. We also examined the relationship between the induced repair response and DNA replication. When cells are treated with hydroxyurea, under conditions that inhibit more than 98% of the DNA synthesis, prior to exposure to 5 Gy, repair patches of 3 and 150 nucleotides are found. This indicates that the longer repair patches are not a result of aberrant DNA replication. However, when cells are treated with the DNA polymerase inhibitor aphidicolin in combination with hydroxyurea and cytosine arabinoside, no induced long patches are found. These results indicate that DNA polymerase alpha, delta or epsilon is required for the synthesis of the VLRP.     

Radiation-induced mutagenicity and lethality in ames tester strains of salmonella

Mutation and killing induced by X radiation and 60CO gamma radiation were studied in six different histidine-requiring auxotrophs of Salmonella typhimurium. Strain TA100, which is sensitive to base-pair substitutions, and strains TA2637 and TA98, which are sensitive to frameshifts, carry the pKM101 plasmid and exhibit significantly higher radiation-induced mutations compared to their plasmidless parent strains TA1535, TA1537, and TA1538, respectively. Among the plasmid-containing strains, TA98 and TA2637 are much more sensitive to the mutagenic action of radiation than is TA100 based on a comparison with their respective spontaneous mutation rates; however, no uniformity was observed in the responses of the strains to the lethal action of ionizing radiation. The pKM101 plasmid provides partial protection against lethality in TA100 and TA2637, whereas the same plasmid enhances the lethal action of ionizing radiation in TA98. The following conclusions are consistent with these observations: (1) the standard Ames Salmonella assay correctly identifies ionizing radiation as a mutagenic agent; (2) frameshift-sensitive parent strains are more sensitive to the mutagenic effects of ionizing radiation than is the only strain studied that is sensitive to base-pair substitutions; and (3) enhancement of mutagenesis and survival is related to plasmid-mediated repair of DNA damage induced by ionizing radiation and does not involve damage induced by Cerenkov-generated uv radiation which is negligible for our irradiation conditions.     

TP53 is not required for the constitutive or induced repair of DNA damage produced by ionizing radiation at the G1/S-phase border

We have previously described a novel DNA repair response that is induced in cells irradiated with ionizing radiation at the G1/S-phase border and is characterized by the formation of very long repair patches (VLRP) containing at least 150 nucleotides. In the current study, we examined whether there is a requirement for TP53 in this induced repair process. We find that in normal cells, the endogenous levels of TP53 are elevated at the G1/S-phase border, and that these levels are not further increased after irradiation with 5 Gy. In cells expressing the E6 oncoprotein of human papillomavirus, which inactivates TP53 function, there is a greatly accentuated induction of the VLRP that nearly masks the constitutive repair response. Incubation of cells in the presence of cycloheximide, which inhibits the induced repair, reveals the presence of the constitutive repair patches. All cells examined continue to replicate their DNA after exposure to ionizing radiation. In contrast, cells irradiated with UV radiation at the G1/S-phase border show an induction of TP53 protein and halt DNA synthesis, but do not induce the VLRP. Our results show that TP53 is not required for the constitutive or induced repair of DNA damage induced by ionizing radiation. In addition, these results suggest that TP53 may suppress the formation of VLRP and that the progression of cells through S phase after exposure to ionizing radiation signals the induced repair response.     

Clustered DNA lesion repair in eukaryotes: relevance to mutagenesis and cell survival

A clustered DNA lesion, also known as a multiply damaged site, is defined as ≥ 2 damages in the DNA within 1-2 helical turns. Only ionizing radiation and certain chemicals introduce DNA damage in the genome in this non-random way. What is now clear is that the lethality of a damaging agent is not just related to the types of DNA lesions introduced, but also to how the damage is distributed in the DNA. Clustered DNA lesions were first hypothesized to exist in the 1990s, and work has progressed where these complex lesions have been characterized and measured in irradiated as well as in non-irradiated cells. A clustered lesion can consist of single as well as double strand breaks, base damage and abasic sites, and the damages can be situated on the same strand or opposing strands. They include tandem lesions, double strand break (DSB) clusters and non-DSB clusters, and base excision repair as well as the DSB repair pathways can be required to remove these complex lesions. Due to the plethora of oxidative damage induced by ionizing radiation, and the repair proteins involved in their removal from the DNA, it has been necessary to study how repair systems handle these lesions using synthetic DNA damage. This review focuses on the repair process and mutagenic consequences of clustered lesions in yeast and mammalian cells. By examining the studies on synthetic clustered lesions, and the effects of low vs high LET radiation on mammalian cells or tissues, it is possible to extrapolate the potential biological relevance of these clustered lesions to the killing of tumor cells by radiotherapy and chemotherapy, and to the risk of cancer in non-tumor cells, and this will be discussed.     

Base excision repair by hNTH1 and hOGG1: a two edged sword in the processing of DNA damage in gamma-irradiated human cells

Using siRNA technology, we down-regulated in human B-lymphoblastoid TK6 cells the two major oxidative DNA glycosylases/AP lyases that repair free radical-induced base damages, hNTH1 and hOGG1. The down-regulation of hOGG1, the DNA glycosylase whose main substrate is the mutagenic but not cytotoxic 8-oxoguanine, resulted in reduced radiation cytotoxicity and decreased double strand break (DSB) formation post-irradiation. This supports the idea that the oxidative DNA glycosylases/AP lyases convert radiation-induced clustered DNA lesions into lethal DSBs and is in agreement with our previous finding that overexpression of hNTH1 and hOGG1 in TK6 cells increased radiation lethality, mutant frequency at the thymidine kinase locus and the enzymatic production of DSBs post-irradiation [N. Yang, H. Galick, S.S. Wallace, Attempted base excision repair of ionizing radiation damage in human lymphoblastoid cells produces lethal and mutagenic double strand breaks, DNA Repair (Amst) 3 (2004) 1323-1334]. Interestingly, cells deficient in hNTH1, the DNA glycosylase that repairs a major lethal single free radical damage, thymine glycol, were more radiosensitive but at the same time fewer DSBs were formed post-irradiation. These results indicate that hNTH1 plays two roles in the processing of radiation damages: repair of potentially lethal single lesions and generation of lethal DSBs at clustered damage sites. In contrast, in hydrogen peroxide-treated cells where the majority of free radical DNA damages are single lesions, the base excision repair pathway functioned to protect the cells. Here, overexpression of hNTH1 and hOGG1 resulted in reduced cell killing while suppression of glycosylase expression resulted in elevated cell death.     

Role for DNA polymerase beta in response to ionizing radiation

Evidence for a role of DNA polymerase beta in determining radiosensitivity is conflicting. In vitro assays show an involvement of DNA polymerase beta in single strand break repair and base excision repair of oxidative damages, both products of ionizing radiation. Nevertheless the lack of DNA polymerase beta has been shown to have no effect on radiosensitivity. Here we show that mouse embryonic fibroblasts deficient in DNA polymerase beta are considerably more sensitive to ionizing radiation than wild-type cells, but only when confluent. The inhibitor methoxyamine renders abasic sites refractory to the dRP lyase activity of DNA polymerase beta. Methoxyamine did not significantly change radiosensitivity of wild-type fibroblasts in log phase. However, DNA polymerase beta deficient cells in log phase were radiosensitized by methoxyamine. Alkaline comet assays confirmed repair inhibition of ionizing radiation induced damage by methoxyamine in these cells, indicating both the existence of a polymerase beta-dependent long patch pathway and the involvement of another methoxyamine sensitive process, implying the participation of a second short patch polymerase(s) other than DNA polymerase beta. This is the first evidence of a role for DNA polymerase beta in radiosensitivity in vivo.