Time-dose relationships in radiation-enhanced integration

Low dose ionizing radiation strongly stimulates insertional mutagenesis in a γH2AX dependent manner

Extrachromosomal DNA can integrate into the genome with no sequence specificity producing an insertional mutation. This process, which is referred to as random integration (RI), requires a double stranded break (DSB) in the genome. Inducing DSBs by various means, including ionizing radiation, increases the frequency of integration. Here we report that non-lethal physiologically relevant doses of ionizing radiation (10-100 mGy), within the range produced by medical imaging equipment, stimulate RI of transfected and viral episomal DNA in human and mouse cells with an extremely high efficiency. Genetic analysis of the stimulated RI (S-RI) revealed that it is distinct from the background RI, requires histone H2AX S139 phosphorylation (γH2AX) and is not reduced by DNA polymerase θ (Polq) inactivation. S-RI efficiency was unaffected by the main DSB repair pathway (homologous recombination and non-homologous end joining) disruptions, but double deficiency in MDC1 and 53BP1 phenocopies γH2AX inactivation. The robust responsiveness of S-RI to physiological amounts of DSBs can be exploited for extremely sensitive, macroscopic and direct detection of DSB-induced mutations, and warrants further exploration in vivo to determine if the phenomenon has implications for radiation risk assessment.

Hyperactivation of DNA-PK by double-strand break mimicking molecules disorganizes DNA damage response

Cellular response to DNA damage involves the coordinated activation of cell cycle checkpoints and DNA repair. The early steps of DNA damage recognition and signaling in mammalian cells are not yet fully understood. To investigate the regulation of the DNA damage response (DDR), we designed short and stabilized double stranded DNA molecules (Dbait) mimicking double-strand breaks. We compared the response induced by these molecules to the response induced by ionizing radiation. We show that stable 32-bp long Dbait, induce pan-nuclear phosphorylation of DDR components such as H2AX, Rpa32, Chk1, Chk2, Nbs1 and p53 in various cell lines. However, individual cell analyses reveal that differences exist in the cellular responses to Dbait compared to irradiation. Responses to Dbait: (i) are dependent only on DNA-PK kinase activity and not on ATM, (ii) result in a phosphorylation signal lasting several days and (iii) are distributed in the treated population in an “all-or-none” pattern, in a Dbait-concentration threshold dependant manner. Moreover, despite extensive phosphorylation of the DNA-PK downstream targets, Dbait treated cells continue to proliferate without showing cell cycle delay or apoptosis. Dbait treatment prior to irradiation impaired foci formation of Nbs1, 53BP1 and Rad51 at DNA damage sites and inhibited non-homologous end joining as well as homologous recombination. Together, our results suggest that the hyperactivation of DNA-PK is insufficient for complete execution of the DDR but induces a “false” DNA damage signaling that disorganizes the DNA repair system.

Nucleotide excision repair proteins and their importance for radiation‐enhanced transfection

PURPOSE

Irradiated cells transfect more efficiently than unirradiated cells because of a radiation-induced increase in plasmid integration. However, the molecular mechanism is unclear. Because of recent observations that nucleotide excision repair (NER) proteins can be involved in certain types of recombination in yeast, it was hypothesized that NER proteins might play a role in this radiation-enhanced integration.

MATERIALS AND METHODS

Hamster and human cells with inactivating mutations in NER genes were irradiated at doses from 0 to 6 Gy and then immediately transfected with a linearized selectable marker plasmid. Transfection-enhancement ratios (TERs) were calculated as the ratio of the number of drug-resistant colonies in unirradiated cells to the number of transfectants in irradiated cells, corrected for cytotoxicity from radiation.

RESULTS

Transfection into unirradiated rodent cells was unaffected by NER mutation status. Transfection into unirradiated human cells, however, was increased by NER mutation. The TERs were 5 and 100 for CHO and primary human fibroblasts, respectively, after exposure of the cells to 6 Gy. Mutations in ERCC1, XPA, XPB, XPC, XPF, XPG and CSB dramatically reduced TER. Mutations in ERCC1, XPC, XPF, XPG and CSB suppressed transfection so that the TER was significantly below 1.

CONCLUSIONS

The mechanism of radiation-enhanced plasmid integration was distinct from that of plasmid integration in unirradiated cells, and NER gene products were critical for enhanced integration to occur.

Ionizing radiation induces microhomology-mediated end joining in trans in yeast and mammalian cells

DNA double-strand breaks repaired through nonhomologous end joining require no extended sequence homology as a template for the repair. A subset of end-joining events, termed microhomology-mediated end joining, occur between a few base pairs of homology, and such pathways have been implicated in different human cancers and genetic diseases. Here we investigated the effect of exposure of yeast and mammalian cells to ionizing radiation on the frequency and mechanism of rejoining of transfected unirradiated linear plasmid DNA. Cells were exposed to gamma radiation prior to plasmid transfection; subsequently the rejoined plasmids were recovered and the junction sequences were analyzed. In irradiated yeast cells, 68% of recovered plasmids contained microhomologies, compared to only 30% from unirradiated cells. Among them 57% of events used>or=4 bp of microhomology compared to only 11% from unirradiated cells. In irradiated mammalian cells, 54% of plasmids used>or=4 bp of microhomology compared to none from unirradiated cells. We conclude that exposure of yeast and mammalian cells to radiation prior to plasmid transfection enhances the frequency of microhomology-mediated end-joining events in trans. If such events occur within genomic locations, they may be involved in the generation of large deletions and other chromosomal aberrations that occur in cancer cells.

Human fibroblasts expressing hTERT show remarkable karyotype stability even after exposure to ionizing radiation

Ectopic expression of telomerase results in an immortal phenotype in various types of normal cells, including primary human fibroblasts. In addition to its role in telomere lengthening, telomerase has now been found to have various functions, including the control of DNA repair, chromatin modification, and the control of expression of genes involved in cell cycle regulation. The investigations on the long-term effects of telomerase expression in normal human fibroblast highlighted that these cells show low frequencies of chromosomal aberrations. In this paper, we describe the karyotypic stability of human fibroblasts immortalized by expression of hTERT. The ectopic overexpression of telomerase is associated with unusual spontaneous as well as radiation-induced chromosome stability. In addition, we found that irradiation did not enhance plasmid integration in cells expressing hTERT, as has been reported for other cell types. Long-term studies illustrated that human fibroblasts immortalized by telomerase show an unusual stability for chromosomes and for plasmid integration sites, both with and without exposure to ionizing radiation. These results confirm a role for telomerase in genome stabilisation by a telomere-independent mechanism and point to the possibility for utilizing hTERT-immortalized normal human cells for the study of gene targeting.

Radiation enhances the anti-tumor effects of vaccinia-p53 gene therapy in glioma

The overall goal of this study was to analyze the effect and mechanism of radiation in combination with vaccinia viruses (VV) carrying the p53 gene against glioma. Comparison of two alternative treatments of cultured C6 (p53(+)) and 9L (p53(-)) rat glioma cells showed significantly reduced survival for both cell lines, especially 9L, when radiation was applied prior to virus versus radiation alone. High p53 protein expression mediated by VV-TK-p53 was measured in infected cells. Single modality treatment of C6 cells with psoralen and UV (PUV)-inactivated VV-TK-p53 (PUV-VV-TK-53) or radiation significantly decreased survival compared with PUV-inactivated L-15 (PUV-L-15) control virus. However, no difference was observed between radiation and combination treatments of C6 cells. In contrast, radiation followed by PUV-VV-TK-53 resulted in dramatic reduction of 9L cell viability, compared to single modality treatment. Flow cytometry analysis of Annexin-V-stained 9L cells showed that radiation and PUV-VV-TK-53 caused a significant decrease in live cells (17.2%) as compared to other treatments and control (61.6-98.3%). Apoptosis was observed in 37.2% of cells, while the range was 0.7-7.8% in other treatment groups; maximal p53 level was measured on day 7 post-infection. In athymic mice bearing C6 tumors, VV-TK-53 plus radiation in both single and multiple therapies resulted in significantly smaller tumors by day 30 compared to the agents given only once. Immunohistochemical analysis of tumor sections demonstrated p53 protein expression over 20 days after VV-TK-53 treatment. Analysis of blood and spleen cells of mice given multiple combination treatments showed significant splenomegaly, leukocytosis, and increased DNA synthesis and response to mitogen. Multiple combination treatments were also associated with significantly elevated natural killer and B cells in the spleen. There were no overt toxicities, although depression in red blood cell and thrombocyte parameters was noted. Collectively, the data demonstrate that radiation significantly improves the efficacy of VV-mediated tumor suppressor p53 therapy and may be a promising strategy for glioma treatment. Furthermore, the results support the conclusion that the mechanisms underlying the enhanced anti-tumor effect of combination treatment include apoptosis/necrosis and upregulation of innate immune defenses.

DNA-PK and ATM are required for radiation-enhanced integration

Ionizing radiation is known to improve transfection of exogenous DNA, a process we have termed radiation-enhanced integration. Previous observations have demonstrated that Ku proteins are critical for radiation-enhanced integration. Since Ku proteins form the DNA-binding domain of DNA-PK and since DNA-PK is important in nonhomologous DNA end joining, it was hypothesized that DNA-PK function might be important for radiation-enhanced integration. The ATM protein has been shown to be important in the recognition of a variety of types of DNA damage and to associate with DNA-PK under certain conditions. It was thus hypothesized that ATM might also play a role in radiation-enhanced integration. To test these hypotheses, radiation-enhanced integration was measured in hamster cells that are defective in the catalytic subunit of DNA-PK and in human cells containing mutant ATM. Radiation-enhanced integration was not detected in any of the cell lines with mutant PRKDC (also known as DNA-PKcs), but it was present in cells of the same lineage with wild-type PRKDC. Radiation-enhanced integration was defective in cells lacking kinase activation. ATM-deficient cell lines also showed defective radiation-enhanced integration. These data demonstrate that DNA-PK and ATM must both be active for radiation-enhanced integration to be observed.