Modification of high LET radiation-induced damage and its repair in yeast by hypoxia.

The lethal response of a diploid yeast strain BZ34 to densely ionizing radiations from the reaction 10B(n, alpha)7 Li was studied. The values for relative biological effectiveness (r.b.e.) and oxygen enhancement ratio (o.e.r.) for this radiation compare favourably with the data obtained with charged particles on the same strain of yeast. Recovery from potentially lethal damage was also studied by post-irradiation holding under non-nutrient conditions. In order to understand the role of oxygen in the recovery process, the investigation covered the following treatment regimens: (a) aerobic irradiation and aerobic holding (A-A), (b) aerobic irradiation and hypoxic holding (A-H), (c) hypoxic irradiation and hypoxic holding (H-H) and (d) hypoxic irradiation and aerobic holding (H-A). It has been found that the presence of oxygen is essential for recovery from the damage induced by both gamma rays and high linear energy transfer (LET) radiations. The extent of recovery was larger for gamma-induced damage than for damage induced by high LET radiation (alpha + 7Li) for the A-A condition. In the H-H condition, while only a slight recovery was seen for gamma-induced damage, it was totally absent for high LET damage. For the modality A-H, it was found that there is not recovery from the sparsely ionising gamma radiation-induced damage. The implications of these results for the treatment of malignant tumours by radiotherapy are briefly discussed.     

Fixation and repair of radiation-induced potentially mutagenic damage sensitive to hypertonic treatment in human diploid fibroblasts

The effect of hypertonic salt treatment on the repair of potentially lethal damage and potentially mutagenic damage in X-irradiated asynchronous and synchronous human diploid fibroblasts (IMR91) have been studied. Resistance to 6-thioguanine was used for the mutagenic end point. When cells in late-S-phase were treated with hypertonic salt solution immediately after X-irradiation, both cell killing and mutation induction were enhanced, as compared to X-irradiation alone. This suggests that X-irradiation of cells in late S phase induces both potentially lethal damage and potentially mutagenic damage and that both are sensitive to hypertonic salt solution. When cells were allowed 2 h for repair after exposure to X-rays, both types of damage were completely repaired. Almost the same results were obtained with asynchronous cells. These results are discussed in terms of the relationship between radiation damage leading to cell lethality and mutagenesis.     

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.     

Interpretation of the dose and LET dependence of RBE values for lethal lesions in yeast cells

Survival data on yeast cells proficient or deficient in the repair of DNA double-strand breaks (dsb) and data on the induction of dsb are used to interpret the dose dependence of the RBE value for lethal lesions after irradiation at high dose rate followed by 72-hr liquid holding providing optimum conditions for repair of potentially lethal lesions (RBEDP, DP = delayed plating). The radiations applied are conventional (150 kV), soft (50 kV), and ultrasoft (4 kV) X rays, 30-MeV electrons (or 60Co gamma rays), and 3.5-MeV alpha particles. Analysis shows that the dose dependence of the RBEDP value can be explained by the combination of two dose-independent RBE values, one for the single-particle traversal effect (RBEspt) and the other for the accumulation of dsb (RBEdsb) due to the traversal of more than one particle through the cell nucleus. Furthermore, it is shown that the LET dependence of RBEspt values describing the linear component of the lethal lesions must be considered separately for "electron" and "particle" radiations.     

Recovery from sublethal and potentially lethal damage in an X-ray-sensitive CHO cell

It has been suggested that DNA strand breaks are the molecular lesions responsible for radiation-induced lethality and that their repair is the basis for the recovery of irradiated cells from sublethal and potentially lethal damage. EM9 is a Chinese hamster ovary cell line that is hypersensitive to killing by X rays and has been reported to have a defect in the rate of rejoining of DNA single-strand breaks. To establish the importance of DNA strand-break repair in cellular recovery from sublethal and potentially lethal X-ray damage, those two parameters, recovery from sublethal and potentially lethal damage, were studied in EM9 cells as well as in EM9's parental repair-proficient strain, AA8. As previously reported, EM9 is the more radiosensitive cell line, having a D0 of 0.98 Gy compared to a D0 of 1.56 Gy for AA8 cells. DNA alkaline elution studies suggest that EM9 cells repair DNA single-strand breaks at a slower rate than AA8 cells. Neutral elution analysis suggests that EM9 cells also repair DNA double-strand breaks more slowly than AA8 cells. All of these data are consistent with the hypothesis that DNA strand-break ligation is defective in EM9 cells and that this defect accounts for increased radiosensitivity. The kinetics and magnitude of recovery from sublethal and potentially lethal damage, however, were similar for both EM9 and AA8 cells. Six-hour recovery ratios for sublethal damage repair were found to be 2.47 for AA8 cells and 1.31 for EM9 cells. Twenty-four-hour recovery ratios for potentially lethal damage repair were 3.2 for AA8 and 3.3 for EM9 cells. Both measurements were made at approximately equitoxic doses. Thus, the defect in EM9 cells that confers radiosensitivity and affects DNA strand-break rejoining does not affect sublethal damage repair or potentially lethal damage repair.     

On the nature of damage involved in liquid-holding recovery in diploid yeast after gamma- and alpha-irradiation.

Cells surviving after liquid-holding recovery following gamma- and alpha-irradiations are found to be slightly more sensitive to a second series of radiation doses. Further, the shoulder on the gamma survival curve of the pre-irradiated and liquid-held cells disappears. The shoulder and sensitivity are restored only when these cells are grown in broth before the second series of doses. In addition to this, liquid-holding recovery reduces progressively if the cells after irradiation are incubated in broth for different periods of time before holding. These observations suggest that: (1) the so-called potentially lethal damage may consitute that part of the sub-lethal damage which interact with one another to form lethal damage; (2) during liquid-holding, the interaction among sub-lethal damage transforming them to the status of lethal damage is inhibited; (3) the 'recovered' cells are saturated with sub-lethal damage, the repair of which will be completed only when the cells are placed in a nutrient medium. The inhibitory process is not a passive one, but requires energy metabolism.     

An acidic extracellular environment reduces the fixation of radiation damage

Chinese hamster ovary cells in exponential growth were irradiated with gamma or X rays in an acidic or alkaline extracellular environment. Incubation in acid medium during or after irradiation reduced the degree of fixation of potentially lethal lesions. Fixation and repair of acid-modified damage occurred with a halftime of 9 to 10 min. The rate of repair of sublethal damage was unaffected by hydrogen ion concentration and progressed with a half-time of 30 min. An acid environment modified only survival of exponentially growing cells; unfed plateau-phase cultures were unaffected.     

Mammalian cell killing by ultrasoft X rays and high-energy radiation: an extension of the MK model

An alternate formulation of the microdosimetric-kinetic (MK) model is presented that applies to irradiation of mammalian cells with ultrasoft X rays as well as high-energy radiations of variable linear energy transfer (LET). Survival and DNA double-strand break measurements for V79 cells from the literature are examined to illustrate application of the model. It is demonstrated that the linear component of the linear-quadratic survival relationship (alpha) is enhanced because repairable potentially lethal lesions formed from a single ultrasoft X-ray energy deposition event, when closer on average than for a single high-energy radiation event, are more likely to combine to form a lethal lesion. The quadratic component (beta) of the linear-quadratic survival relationship is increased because the potentially lethal lesions formed by ultrasoft X rays are created with greater efficiency than those of high-energy radiation. In addition, potentially lethal lesions from very low-energy carbon K-shell X rays may be enriched in structural forms that favor combination to form lethal lesions instead of repair. These features account for the increased effectiveness of killing of V79 cells by ultrasoft X rays compared to cobalt-60 gamma radiation. The importance of pairwise combination of potentially lethal lesions to form exchange chromosome aberrations that become lethal lesions is discussed. The extended MK model explains and reconciles differences between the MK model and the theory of dual radiation action on the one hand, and on the other, the view that variation in the RBE with radiation quality is explained by differences in energy deposition in nanometer- rather than micrometer-size volumes.     

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.     

Effect of dose rate on the survival of irradiated human skin fibroblasts.

The survival of cells in density-inhibited, confluent cultures maintained at 37 degrees C was examined following exposure to 137Cs gamma rays at low dose rates (0.023 or 0.153 Gy/h) or to 60Co gamma rays at a single high dose rate (0.70-0.75 Gy/min). Cells from an ataxia telangiectasia (AT) homozygote showed no dose-rate effect, whereas a three- to fivefold increase in D0 was observed for all other cell strains exposed at low dose rates. The magnitude of the dose-rate effect did not differ significantly among cells from persons with hereditary retinoblastoma, basal cell nevus syndrome, or AT-heterozygote compared with normal cell strains, and was not related to the size of the shoulder (extrapolation number) of the survival curve. Furthermore, no differences in the capacity for the repair of potentially lethal damage during confluent holding were observed among these latter cell strains.     

Repair of potentially lethal damage in unfed plateau phase cultures of Ehrlich ascites tumour cells. II. Monolayer cultures

Monolayer cultures of EAT cells when plated immediately after irradiation show a desrease in survival as they "age" in the plateau phase of growth. This decrease, which is manifest as a diminution of the shoulder width of the survival curve down to values approaching zero, is reversible if the cells are kept in their growth medium for some hours after irradiation before trypsinization and plating. Survival curves obtained by this holding procedure are similar in shape to those shown by exponentially growing or early plateau phase cells. We interpret this effect in terms of repair of potentially lethal damage which occurs after immediate plating in young cultures but only declared during plating in cultures which have "aged" in the plateau phase. The kinetics of this repair and the effects caused by the addition of serum after irradiation in the cultures have been studied.     

Effect of gamma-ray irradiation on Escherichia coli motility

The effects of ionizing radiation on bacteria are generally evaluated from the dose-dependent survival ratio, which is determined by colony-forming ability and mutation rate. The mutagenic damage to cellular DNA induced by radiation has been extensively investigated; however, the effects of irradiation on the cellular machinery in situ remain unclear. In the present work, we irradiated Escherichia coli cells in liquid media with gamma rays from ⁶⁰Co (in doses up to 8 kGy). The swimming speeds of the cells were measured using a microscope. We found that the swimming speed was unaltered in cells irradiated with a lethal dose of gamma rays. However, the fraction of motile cells decreased in a dose-dependent manner. Similar results were observed when protein synthesis was inhibited by treatment with kanamycin. Evaluation of bacterial swimming speed and the motile fraction after irradiation revealed that some E. coli cells without the potential of cell growth and division remained motile for several hours after irradiation.     

The effect of functional inactivation of TP53 by HPV-E6 transformation on the induction of chromosome aberrations by gamma rays in human tumor cells

The influence of expression of TP53 (formerly known as p53) on the induction of chromosome aberrations by gamma rays was examined in an isogenic pair of human tumor cell lines where TP53 expression was normal or inactivated by human papillomavirus (HPV) type 16 E6 expression. Plateau-phase cultures were exposed to 0-8 Gy gamma rays and then either immediately released by subculture or held for 24 h prior to subculture and subsequent cytogenetic analysis. Aberration frequency was determined only in cells entering their first mitosis after irradiation, and cells were sampled over a 48-h period to include cells whose progression into mitosis was delayed. While aberration frequencies were similar at early harvest times, there was evidence for a subpopulation of more heavily damaged cells in the E6-transformed cells that cycled into late mitosis. Holding cells noncycling for 24 h to allow repair of potentially lethal damage eliminated this subpopulation of more heavily damaged cells. The E6-transformed cells also had higher levels of chromatid-type aberrations and sister chromatid exchanges, consistent with an additional defect in kinetics of repair of base damage that is associated with the E6 transformation. Holding cells noncycling for 24 h eliminated the elevated levels of chromatid-type aberrations and sister chromatid exchanges. These studies demonstrate that E6 transformation of human tumor cells will influence both the frequency and types of chromosome aberrations observed after radiation exposure, and that these effects are related to the expression of potentially lethal damage.     

The role of gap junction communication and oxidative stress in the propagation of toxic effects among high-dose α-particle-irradiated human cells

We investigated the roles of gap junction communication and oxidative stress in modulating potentially lethal damage repair in human fibroblast cultures exposed to doses of α particles or γ rays that targeted all cells in the cultures. As expected, α particles were more effective than γ rays at inducing cell killing; further, holding γ-irradiated cells in the confluent state for several hours after irradiation promoted increased survival and decreased chromosomal damage. However, maintaining α-particle-irradiated cells in the confluent state for various times prior to subculture resulted in increased rather than decreased lethality and was associated with persistent DNA damage and increased protein oxidation and lipid peroxidation. Inhibiting gap junction communication with 18-α-glycyrrhetinic acid or by knockdown of connexin43, a constitutive protein of junctional channels in these cells, protected against the toxic effects in α-particle-irradiated cell cultures during confluent holding. Upregulation of antioxidant defense by ectopic overexpression of glutathione peroxidase protected against cell killing by α particles when cells were analyzed shortly after exposure. However, it did not attenuate the decrease in survival during confluent holding. Together, these findings indicate that the damaging effect of α particles results in oxidative stress, and the toxic effects in the hours after irradiation are amplified by intercellular communication, but the communicated molecule(s) is unlikely to be a substrate of glutathione peroxidase.     

Reduction of background mutations by low-dose X irradiation of Drosophila spermatocytes at a low dose rate

A sex-linked recessive lethal mutation assay was performed in Drosophila melanogaster using immature spermatocytes and spermatogonia irradiated with X rays at a high or low dose rate. The mutation frequency in the sperm irradiated with a low dose at a low dose rate was significantly lower than that in the sham-irradiated group, whereas irradiation with a high dose resulted in a significant increase in the mutation frequency. It was obvious that the dose-response relationship was not linear, but rather was U-shaped. When mutant germ cells defective in DNA excision repair were used instead of wild-type cells, low-dose irradiation at a low dose rate did not reduce the mutation frequency. These observations suggest that error-free DNA repair functions were activated by low dose of low-dose-rate radiation and that this repaired spontaneous DNA damage rather than the X-ray-induced damage, thus producing a practical threshold.     

Mutation induction by very low dose rate gamma rays in cultured mouse leukemia cells L5178Y

Induction of cell killing and mutation to 6-thioguanine resistance was studied in growing mouse leukemia cells in culture following gamma rays at dose rates of 30 Gy/h, 20 cGy/h, and 6.3 mGy/h, i.e., acute, low dose rate, and very low dose rate irradiation. A marked increase was observed in the cell survival with decreasing dose rate; no reduction in the surviving fraction was detected after irradiation at 6.3 mGy/h until a total dose of 4 Gy. Similarly, the induced mutation frequency decreased after low dose rate irradiation compared to acute irradiation. However, the frequency after irradiation at 6.3 mGy/h was unexpectedly high and remained at a level which was intermediate between acute and low dose rate irradiation. No appreciable changes were observed in the responses to acute gamma rays (in terms of cell killing and mutation induction) in the cells which had experienced very low dose rate irradiation.     

Repeated doses of gamma rays induce resistance to N-methyl-N'-nitro-N-nitrosoguanidine in Chinese hamster cells

Chinese hamster V79 cells were preirradiated repeatedly with gamma rays and then exposed to ultraviolet (uv) light or N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). The cell killing and induction of mutation at the hypoxanthine-guanine phosphoribosyltransferase locus were examined following these treatments. Cells preirradiated with multiple fractions of gamma rays exhibit the same sensitivity to uv light as the control cells with respect to cell survival and mutation induction. Following treatment with MNNG, resistance to cell killing was observed along with a decreased frequency of mutations induced. These results indicate that the progeny of cells irradiated with multiple fractions of gamma rays could display subsequent changes in sensitivity to lethal and mutagenic effects of additional treatment with DNA-damaging agents.     

Evidence for reduced capacity for damage accumulation and repair in plateau-phase C3H 10T1/2 cells following multiple-dose irradiation with gamma rays

The effects of multiple-dose gamma irradiation on the shape of survival curves were studied with mouse C3H 10T1/2 cells maintained in contact-inhibited plateau phase. The dose-fractionation intervals included 3, 6, and 24 h. Following three fractionated doses (5 Gy per dose) of exposures, cells responded to further irradiation by displaying a survival curve with a much reduced shoulder width (Dq) compared to that of the survival curve measured in cells irradiated with single-graded doses alone. The effect on the mean lethal dose (D0) was small and appeared to be significant. The effect on reduction of Dq could not be completely overcome by lengthening the fractionation intervals from 3 to 6 h or 24 h, times in which repair of sublethal damage (SLD) measured by simple split-dose scheme and potentially lethal damage (PLD) measured by postirradiation incubation was completed. Other experiments showed that pretreatments of cells with fractionated irradiation appeared to slow down the cellular repair processes of SLD and PLD. Therefore, the observed change in the shape of survival curves after fractionation treatments may be attributed to a reduction of the cells' capacity for damage accumulation by an enhancement of the lethal expression of SLD and PLD. Although the molecular mechanism(s) is not known, the results of this study indicate that the acute graded dose-survival curve cannot be used a priori to extrapolate and reliably predict results of hyperfractionation. It is probable that for a nondividing or slowly dividing cell population, such an extrapolation may lead to an underestimation of cell killing. Furthermore, the findings of this investigation appear to support an interpretation, alternative to the high-linear energy transfer (LET) track-end postulate, for the effects on cell survival seen at low doses or low dose rates.     

The relative biological effectiveness of 14.5-MeV neutrons for the induction of gene conversion and mutation in yeast

The relative biological effectiveness (RBE) and oxygen enhancement ratio (OER) were determined in the yeast Saccharomyces cerevisiae for the induction of gene conversion (the product of recombinational repair) and mutation (the product of error prone repair) by 14.5-MeV neutrons in comparison with 60Co gamma rays and 150 KVp X rays. Neutron irradiation in oxic or anoxic conditions induced significantly higher yields of convertants and mutants than sparsely ionizing radiations under the same conditions. RBEs for both gene conversion and mutation under anoxia were significantly higher than under oxic conditions. RBEs for mutant induction under anoxia were lower than the RBEs for gene conversion under the same conditions. The data support the hypothesis that the production of lesions leading to the genetic consequences of gene conversion and mutation differ in their dependence upon LET and the presence of oxygen during irradiation, and therefore the two DNA repair processes which produce these end points recognize, at least in part, different classes of damage.     

Lethal and potentially lethal lesions induced by radiation--a unified repair model

A model of radiation action is described which unifies several of the major existing concepts which have been applied to cell killing. Called the lethal and potentially lethal (LPL) model, it combines the ideas of lesion interaction, irreparable lesions caused by single tracks, linear lesion fixation, lesion repair via first-order kinetics, and binary misrepair. Two different kinds of lesions are hypothesized: irreparable (lethal) and repairable (potentially lethal) lesions. They are tentatively being identified with DNA double-strand breaks of different severity. Two processes compete for depletion of the potentially lethal lesions: correct repair following first-order kinetics, and misrepair following second-order kinetics. Fixation of these lesions can also occur. The model applies presently only to plateau (stationary)-phase cells. Radiobiological phenomena described include effects of low dose rate, high LET, and repair kinetics as measured with repair inhibitors such as hypertonic solution and beta-arabinofuranosyladenine (beta-araA). One consequence of the model is that repair of sublethal damage and the slow component of the repair of potentially lethal damage are two manifestations of the same repair process. Hypertonic treatment fixes a completely new class of lesions which normally repair correctly. Another consequence of the model is that the initial slope of the survival curve depends on the amount of time available for repair after irradiation. The "dose-rate factor" occurring in several linear-quadratic formulations is shown to emerge when appropriate low-dose and long-repair-time approximations are made.