Repair of potentially lethal X-ray damage in fibroblasts derived from patients with hereditary and D-deletion retinoblastoma

We examined X-ray induced potentially lethal damage repair (PLDR) in density inhibited plateau phase cultures of six fibroblast strains derived from patients with hereditary retinoblastoma and two patients with D-deletion retinoblastoma and compared them to three normal controls. PLD was measured in hereditary retinoblastoma (7 Gy exposure) and normal cells (7 and 9 Gy exposure) after 24 h repair time. PLD survival curves were performed at 2-9 Gy on six retinoblastoma and three normal control cell strains. Thus, PLDR was compared at equitoxic survival levels as well as after exposure to equal doses of radiation. Some retinoblastoma strains showed normal PLDR whereas others were possibly deficient. Implications of PLDR for susceptibility to radiation-induced and spontaneous tumours in hereditary retinoblastoma patients are discussed.     

Repair of potentially lethal radiation damage in confluent and non-confluent cultures of human hybrid cells

The repair of potentially lethal damage (PLDR) in a gamma-irradiated human hybrid cell line (skin fibroblast X HeLa) and its tumourigenic segregant has been studied as a function of cell density at the time of irradiation and during the postirradiation repair period. The data show that PLDR occurs in both non-confluent and confluent cultures of both cell lines. Furthermore, there is evidence that the extent of PLDR is dependent on cell density and that cell-cell contact may be an important factor in this regard.     

Effect of hypoxia on recovery from damage induced by heat and radiation in plateau-phase CHO cells

The effect of hypoxia on the induction of and recovery from damage by radiation alone and in combination with heat has been investigated using plateau-phase Chinese hamster ovary (CHO) cells. Postirradiation hypoxia reduced the potentially lethal damage recovery (PLDR) in cells irradiated under an euoxic state and completely eliminated PLDR in cells irradiated under hypoxia. Cells which were maintained under hypoxia during both irradiation and a 4-hr recovery period and then incubated for a further period of 4 hr under euoxic conditions showed PLDR, suggesting that the inhibition of PLDR by hypoxia is reversible. Oligomycin, an inhibitor of energy metabolism, completely eliminated PLDR when present at a concentration of 1 microM during the postirradiation period. Pre- or postirradiation heat treatment at 42.5 degrees C for 30 min appreciably sensitized the cells to the induction of lethality. Thermal enhancement ratio (TER) was 1.7 for cells irradiated and heat treated under hypoxic conditions. The same heat treatment reduced the oxygen enhancement ratio (OER) associated with gamma radiation from 3.1 to 2.5. Cells subjected to this postirradiation heat treatment showed a small extent of PLDR, whereas the pre-heat-treated cells showed as much recovery as non-heat-treated cells. When hypoxic conditions prevailed during the post-treatment incubation period, PLDR was reduced in preheated cells and completely eliminated in postheated cells. The kinetics of interaction between heat and radiation damage were studied by introducing a time gap of 4 hr between the treatments. Cells maintained under euoxic conditions between the treatments showed an appreciable decrease in interaction, suggesting recovery from damage induced by the first treatment. Hypoxic conditions intervening the two treatments largely inhibited the loss of sensitization. Analysis of the results suggests that cells fail to recover from sublethal heat damage when held for 4 hr under hypoxic conditions. Cells held under hypoxic conditions partly recover from the radiation damage which subsequently interacts with sublethal heat damage, resulting in cell lethality.     

Potentially lethal damage repair in cell lines of radioresistant human tumours and normal skin fibroblasts

Radiation cell survival data were obtained in vitro for three cell lines isolated from human tumours traditionally considered to be radioresistant--two melanomas and one osteosarcoma--as well as from a diploid skin fibroblast cell line. One melanoma cell line was much more radioresistant than the other, while the osteosarcoma and fibroblast cell lines were more radiosensitive than either. For cells growing exponentially, little potentially lethal damage repair (PLDR) could be demonstrated by comparing survival data for cells in which subculture was delayed by 6 h with those sub-cultured immediately after treatment. For the malignant cells in plateau phase, which in these cells might be better termed 'slowed growth phase', since an appreciable fraction of the cells are still cycling, a small amount of PLDR was observed, but not as much as reported by other investigators in the literature. The normal fibroblasts, which achieved a truer plateau phase in terms of noncycling cells, showed a significantly larger amount of PLDR than the tumour cells.     

Fixation and repair by anisotonic treatment of radiation damage leading to oncogenic transformation

Mouse embryo (C3H 10T1/2) cells were exposed to anisotonic NaCl solutions or combined treatments of radiation and anisotonic solutions. Anisotonic treatment with 0.05 or 0.5 mol/l solutions did not cause transformation and only prolonged exposure at 1.5 mol/l caused significant increases in transformation. When cells were irradiated in the presence of 0.05 mol/l NaCl, increased transformation occurred than when cells were irradiated in medium. Thus, anisotonic treatment after irradiation resulted in fixation of potentially lethal and transformed radiation damage. Fixation of potentially transformed damage was greater for cells irradiated in the presence of 0.05 mol/l NaCl than for cells irradiated in medium. When the NaCl treatment after irradiation was delayed by incubation at 37 degrees C, recovery of potentially lethal and potentially transformed damage was observed.     

Metabolic effects of 3'-deoxyadenosine (cordycepin) and 2-halo-3'-deoxyadenosine on repair of X-ray-induced potentially lethal damage in Chinese hamster V79 cells

Using cultured Chinese hamster V79 cells, an attempt has been made to examine the phosphorylation of cordycepin and its 2-halo derivatives (2-chloro-3'-deoxyadenosine, 2-bromo-3'-deoxyadenosine, and 2-iodo-3'-deoxyadenosine) by adenosine kinase, within the cells, and to correlate it with their cytotoxicities and abilities to inhibit the repair of X-ray-induced potentially lethal damage (PLDR). Of all compounds, only cordycepin was found to be phosphorylated and showed both potent cytotoxicity and ability to inhibit PLDR.     

Fixation of potentially lethal radiation damage by post-irradiation exposure of Chinese hamster cells to 0.5 M or 1.5 M NaCl solutions.

The effect of 0.05 M and 1.5 M NaCl treatments on CHO cells during and after irradiation has been examined. Treatment with either hypotonic or hypertonic salt solutions during and after irradiation resulted in the fixation of radiation damage which would otherwise not be expressed. The half time for fixation was 4 to 5 min, and the increased expression of the potentially lethal damage by anisotonic solutions was mainly characterized by large decreases in the shoulder of the survival curve, as well as by decreases in DO. Fixation of radiation damage at 37 degrees C occurred to a much greater extent for the hypertonic treatment than for the hypotonic treatment and was greater at 37 degrees C than at 20 degrees C. Although both the hypotonic and hypertonic treatments during and after irradiation reduced or eliminated the repair of sublethal and potentially lethal damage, treatment during irradiation only, radiosensitized the cells when the treatment was hypotonic, and radioprotected the cells when the treatment was hypertonic. These observations are discussed in relation to salt treatments and different temperatures altering competition between repair and fixation of potentially lethal lesions, the number of which depends on the particular salt treatment at the time of irradiation.     

pH-dependent effects of the ionophore nigericin on response of mammalian cells to radiation and heat treatment

The extracellular pH (pHe) in many solid tumors is often lower than the pH of normal tissues. The K+/H+ ionophore nigericin is toxic to CHO cells when pHe is below but not above 6.5, and thus it has potential for selective killing of tumor cells in an acidic environment. This study examines the pH-dependent effects of nigericin on the response of CHO cells to radiation and heat treatment. Cells held for 4 h in Hank's balanced salt solution, after 9 Gy irradiation, exhibit potentially lethal damage recovery (PLDR) which is maximal at pHe 6.7-6.8. Addition of nigericin, postirradiation, not only inhibits PLDR when pHe is below 6.8, but interacts synergistically with radiation to reduce survival below that of cells plated immediately after irradiation when pHe is 6.4 or lower. Nigericin enhances heat killing of CHO cells perferentially under acidic conditions, and where neither heat nor drug treatment alone is significantly toxic. Survival of cells held for 30 min at 42.1 degrees C in the presence of 1.0 microgram/ml nigericin is 0.6, 0.08, 0.003, and 0.00003 at pHe 7.4, 6.8, 6.6, and 6.4, respectively, relative to survival of 1.0 in untreated cultures. The biochemical effects of nigericin at pHe 7.4 vs pHe 6.4 have been investigated. Nigericin inhibits respiration, stimulates glucose consumption, and causes dramatic changes in intracellular concentrations of Na+ and K+ at pHe 7.4 as well as 6.4. The drug reduces intracellular levels of ATP, GTP, and ADP but has more pronounced effects under acidic incubation conditions. Others have shown that nigericin equilibrates pHe and intracellular pH (pHi) only when pHe is 6.5 or lower. Our observations and those of others have led us to conclude that lowering of pHi by nigericin is either the direct or indirect cause of enhancement of radiation and heat killing of cells in an acidic environment.     

Radiation response characteristics of human cells in vitro

Improvements in tissue culture techniques and growth media have made it possible to culture a range of cells of human origin, both normal and malignant. The most recent addition to the list are endothelial cells from umbilical cord veins. Interesting results in radiosensitivity studies of these human cells have been obtained, some of which may have implications in radiation therapy. (i) Repair of potentially lethal damage (PLDR) has been observed in all cell lines investigated; cells of normal origin repair PLD at least as well as malignant cells, which makes clinical trials of PLDR inhibitors of doubtful usefulness. (ii) No apparent correlation can be made between the extent of PLDR and the traditional radioresponsiveness of a particular tumor type. Indeed, if anything, it could appear to have an inverse correlation since the most resistant tumor cells show the smallest amount of PLD repair. (iii) Dose-rate effects appear to be better predictors of radiosensitivity than PLDR capacity. (iv) Sublethal damage repair, manifest by a dose-rate effect, has also been observed in all human cell lines tested. Cells of normal tissue origin, including fibroblasts and endothelial cells, exhibit a dose-rate effect that is intermediate between that for cells from traditionally resistant tumors (melanoma and osteosarcoma) and cells from more sensitive tumors (neuroblastoma and breast).     

Evidence for the repair of potentially lethal damage in irradiated bone marrow

Summary The effects on cell survival of maintaining bone marrow cells (CFU-S) in situ following irradiation and before assay by transplantation was investigated. When the CFU-S cells are maintained in situ following irradiation survival drops and plateaus at about 9 h post-irradiation. Evidence is presented that this decrease in survival may be due to potentially lethal damage repair (PLD) inhibition caused by post-irradiation in situ holding. This effect on PLD repair is different than that usually found in cells in vitro and in vivo tumors in that it mainly alters the shoulder rather than the slope of the survival curve of CFU-S cells. It is different than PLDR found in vivo for normal mammary and thyroid gland epithelial cells because in situ holding decreases rather than increases the survival of CFU-S cells. Evidence is also presented that the radiation survival curve for in situ bone marrow cells (CFU-S) may not have a shoulder.Supported in part by NIH, NCI grants P01 CA 19298 and P30 CA 14520Supported in part by an American Cancer Society Clinical Fellowship     

Radiosensitization of GL261 glioma cells by tetraiodothyroacetic acid (tetrac)

We studied effects of tetrac (tetraiodothyroacetic acid) on survival of GL261, a murine brain tumor cell line, following single doses of 250 kVp x-rays and on repair of damage (sublethal and potentially lethal damage repair; SLDR, PLDR) in both exponential and plateau phase cells. Cells were exposed to 2 μM tetrac (1 h at 37oC) prior to x-irradiation. At varying times after irradiation, cells were re-plated in medium without tetrac. Two weeks later, colonies were counted and results analyzed using either the linear-quadratic (LQ) or single-hit, multitarget (SHMT) formalisms. Tetrac sensitized both exponential and plateau phase cells to x-irradiation, as shown by a decrease in the quasi-threshold dose (Dq), leading to an average tetrac enhancement factor (ratio of SF2 values) of 2.5. Tetrac reduced SLDR in exponential cells by a factor of 1.8. In plateau phase cells there was little expression of SLDR, but tetrac produced additional cell killing at 1-4 h after the first dose. For PLDR expression in exponential cells, tetrac inhibited PLDR by a factor of 1.9, and in plateau phase cells, tetrac decreased PLDR expression by a factor of 3.4. These data show that the decreased Dq value seen after single doses of x-rays with tetrac treatment is also accompanied by a significant decrease in recovery from sublethal and potentially lethal damage.     

Decay of γ-H2AX foci correlates with potentially lethal damage repair and P53 status in human colorectal carcinoma cells

The influence of p53 status on potentially lethal damage repair (PLDR) and DNA double-strand break (DSB) repair was studied in two isogenic human colorectal carcinoma cell lines: RKO (p53 wild-type) and RC10.1 (p53 null). They were treated with different doses of ionizing radiation, and survival and the induction of DNA-DSB were studied. PLDR was determined by using clonogenic assays and then comparing the survival of cells plated immediately with the survival of cells plated 24 h after irradiation. Doses varied from 0 to 8 Gy. Survival curves were analyzed using the linear-quadratic formula: S(D)/S(0) = exp-(αD+βD²). The γ-H2AX foci assay was used to study DNA DSB kinetics. Cells were irradiated with single doses of 0, 0.5, 1 and 2 Gy. Foci levels were studied in non-irradiated control cells and 30 min and 24 h after irradiation. Irradiation was performed with gamma rays from a ¹³⁷Cs source, with a dose rate of 0.5 Gy/min. The RKO cells show higher survival rates after delayed plating than after immediate plating, while no such difference was found for the RC10.1 cells. Functional p53 seems to be a relevant characteristic regarding PLDR for cell survival. Decay of γ-H2AX foci after exposure to ionizing radiation is associated with DSB repair. More residual foci are observed in RC10.1 than in RKO, indicating that decay of γ-H2AX foci correlates with p53 functionality and PLDR in RKO cells.     

The effect of pH on potentially lethal damage recovery in A549 cells

The radiation sensitivity and potentially lethal damage recovery (PLDR) capacity of A549 human lung carcinoma cells have been studied. For unfed monolayer cultures, radiation sensitivity was greater in plateau phase than in log phase of growth. PLDR was observed when plateau-phase cells were held in their own spent medium postirradiation, such that the dose-response curve with 24 h holding was similar to that for log-phase cells plated immediately after irradiation. The high PLDR capacity of A549 plateau-phase cells (recovery factor between 40 and 70 for 24 h holding after 10 Gy) was reduced 10-fold or more by alkalinizing the pH of the spent medium immediately after irradiation from a value of 6.5 +/- 0.1 to a value of 7.6. Medium alkalinization resulted in an increase in the rate of glycolysis, with subsequent reacidification to a pH of 7.3 within 2 h of the pH adjustment. No change in cell cycle distribution was observed in the plateau-phase cultures up to 32 h after change of medium pH, and no increase in cell density was found after 48 h. A slight increase in the rate of incorporation of radiolabeled thymidine into acid-precipitable material was observed at 4 and 24 h after alkalinization of the medium. While it is not possible at present to define a mechanism for this pH effect, our results demonstrate that, at least for this cell line, variables such as medium pH and glucose concentration can profoundly influence the observation of PLDR.     

Effect of melanin on radiation response of CHO cells

The effect of the presence of melanin on the response of mammalian cells to ionizing radiation was investigated in a model system utilizing the ability of Chinese hamster ovary cells to incorporate melanin by endocytosis. Cells were incubated in monolayer cultures from 2 to 20 hours with melanin prepared from 'beef eye' or synthesized by air oxidation of 3,4-dihydroxyphenylalanine. For asynchronous cultures, the survival curve parameters for cells incubated with both types of melanin were indistinguishable from those of the same cells without added melanin. The radiation response to fractionated doses of 6 Gy separated by various periods did not indicate any effect of melanin on the extent or kinetics of repair of sublethal damage. Likewise, the repair of potentially lethal damage in plateau phase cultures was unaffected by the presence of melanin. Thus the explanation for the clinical radiation resistance of melanomas in the absence of a direct radiation effect might more likely be found in consideration of other factors such as the role of melanin in oxygen consumption or in differentiation.     

Interaction between radiation and drug damage in mammalian cells. V. DNA damage and repair induced in LZ cells by adriamycin and/or radiation

A multi-drug-resistant cell line selected in increasing concentrations of Adriamycin and designated LZ (J. A. Belli, Radiat. Res. 119, 88-100, 1989) is shown to exhibit a survival response characterized by radiation sensitivity and Adriamycin resistance. To determine if this response is due to alterations in either the initial levels of damage induced or the repair of DNA damage, LZ cells and the parental V79 cells were exposed to either radiation or Adriamycin and the damage and repair were measured with alkaline or nondenaturing filter elution. After exposure to radiation, induction and repair of both single-strand and double-strand breaks were equivalent. LZ cells exposed to 100 micrograms/ml Adriamycin for 1 h contained no measurable damage while the same treatment induced breaks and crosslinks in V79 cells. Pretreatment of LZ cells for 1 h with Adriamycin before irradiation did not alter either the initial levels of induced damage or the repair of strand breakage. These results suggest that (1) mechanisms other than differential induction and repair of strand breaks are responsible for the increased radiation sensitivity in LZ, and (2) the lack of Adriamycin-induced DNA damage in LZ is at least partially responsible for the increased cell survival after treatment.     

Reduced repair of potentially lethal radiation damage in glutathione synthetase-deficient human fibroblasts after X-irradiation

Using a human fibroblast strain deficient in glutathione synthetase and a related proficient control strain, the role of glutathione (GSH) in repair of potentially lethal damage (PLD) has been investigated in determining survival by plating cells immediately or 24 h after irradiation. After oxic or hypoxic irradiation, both cell strains repair radiation-induced damage. However, under hypoxic conditions, the proficient cells repair PLD as well as under oxic conditions while the deficient cells repair less PLD after irradiation under hypoxic than under oxic conditions. Therefore, the oxygen enhancement ratio (o.e.r.) for proficient cells is similar whether the cells are plated immediately or 24 h later (2.0 and 2.13, respectively). In contrast, the o.e.r. for deficient cells is lower when the cells are plated 24 h after irradiation than when they are plated immediately thereafter (1.16 as compared to 1.55). The results indicate that GSH is involved in PLD repair and, in particular, in the repair of damage induced by radiation delivered under hypoxic conditions.     

Quantitative aspects of repair of potentially lethal damage in mammalian cells.

Stationary cultures of Ehrlich ascites tumour cells have been irradiated with X-rays and then immediately or after a time interval trep plated to measure the survival. The increase in survival observed after delayed plating is interpreted as repair of potentially lethal damage. A cybernetic model is used to analyse these data. Three states of damage are assumed for the cells. In state A the cells can grow to macrocolonies, in state B the cells have suffered potentially lethal damage and can grow to macrocolonies only if they are allowed to repair the damage and in state C the cells are lethally damaged. A method of deriving the values of the parameters of the model from the experimental data is given. The dependence of the reaction rate constant of the repair of potentially lethal damage on the dose D is used to derive a possible mechanism for the production of the shoulder in the dose effect curve. Finally this model is compared with other models of radiation action on living cells.     

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.     

Poly(ADP-ribose) and the response of cells to ionizing radiation

The activity of poly(ADP-ribose) polymerase is stimulated by DNA damage resulting from treatment of cells with ionizing radiation, as well as with DNA-damaging chemicals. The elevated polymerase activity can be observed at doses lower than those necessary for measurable reduction in cellular NAD concentration (less than 20 Gy). Several nuclear proteins, including the polymerase itself, are poly(ADP-ribosylated) at elevated levels in irradiated Chinese hamster cells. The addition of inhibitors of poly(ADP-ribose) polymerase to irradiated cells has been found to sensitize the cells to the lethal effects of the radiation, to inhibit the repair of potentially lethal damage, and to delay DNA strand break rejoining. Because of the nonspecificity of the inhibitors, however, it is as yet unknown whether their effects are directly related to the inhibition of poly(ADP-ribose) polymerase, to interference with the poly(ADP-ribosylation) of one or more chromosomal proteins, or to effects unrelated to the poly(ADP-ribosylation) process. The data are consistent with the involvement of poly(ADP-ribose) in the repair of radiation damage, but the nature of this involvement remains to be elucidated.     

Response of X-ray-sensitive CHO mutant cells to gamma radiation. I. Effects of low dose rates and the process of repair of potentially lethal damage in G1 phase

X-ray-sensitive CHO mutants (xrs-5 and xrs-6) were exposed to isoleucine-deficient (IL-) medium for 24-36 h to accumulate G1-phase cells. Cells exposed to IL- medium for up to 5 days did not show significant changes in plating efficiency when returned to normal medium. Nearly confluent cultures of IL- -treated cells were irradiated with either 60Co gamma rays (75 cGy/min) or 137Cs gamma rays (2.7, 6.0, or 15.3 cGy/h). A significant reduction (approximately 2.5-fold) in the radiation sensitivity of the parental CHO K-1 cells was observed for chronic low-dose-rate radiation exposure compared to the results obtained for acute high-dose-rate exposure. However, no noticeable differences were observed in the survival curves of either xrs-5 or xrs-6 cells when low-dose-rate and acute exposures were compared. CHO K-1 cells exhibited potentially lethal damage repair while held in IL- medium after gamma irradiation, whereas no repair was observed in either of the radiation-sensitive mutant lines examined at similar survival levels.