Aphidicolin promotes repair of potentially lethal damage in irradiated mammalian cells synchronized in S-phase

Aphidicolin, an inhibitor of the α-polymerase in mammalian cells, at a concentration of 0.5 μg/ml, is shown to enable cells which are growing exponentially and synchronized in the S-phase of the cell cycle, to repair potentially lethal damage caused by exposure to either x-rays or UV-light. The drug holds cells up in the S-phase which may serve to allow time for repair and could prevent fixation of damage which may occur when the cells progress through the cell cycle. The possible involvement of α- and β-polymerase in repair of potentially lethal damage is discussed.     

Method for probing cells in radiation-induced G2 arrest: demonstration of potentially lethal damage repair

Chinese hamster ovary cells were arrested in the G2 phase of the cell cycle by X-irradiation. When subsequently treated with 5 mM caffeine the arrested population progressed into mitosis as a synchronous cohort where it was harvested by mitotic cell selection. This procedure provides a means to isolate cell populations treated in G2, for the investigation of G2 arrest. Comparisons were made of the number of cells retrieved from G2 arrest with the number suffering arrest, as determined by flow cytometry and by matrix algebraic simulations of irradiated cell progression. The retrieved population was not significantly less than expected for doses up to 3.5 Gy, indicating that the retrieval process does not favour the isolation of any population subset below this dose. Cell populations retrieved from arrest at varying intervals (0-3 h) after irradiation (0-3.5 Gy) showed an increase in survival with increase in interval, consistent with repair of potentially lethal damage. The repair curves (surviving fraction vs time) were each described by a single exponential. G2 cells that were brought to mitosis without a period of arrest exhibited the same radiation response as cells irradiated in mitosis.     

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     

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.     

Novobiocin inhibits the repair of potentially lethal damage but not the repair of sublethal damage

Because of the critical role of the DNA topoisomerases in the synthesis and conformation of DNA, and the well-known observation that radiation inhibits replicative DNA synthesis, we have examined the possibility that inhibitors of these enzymes might influence radiation lethality. In particular, using protocols involving the administration of either fresh or conditioned medium, we examined the ability of intercalative and nonintercalative inhibitors to affect the expression of potentially lethal damage and/or sublethal damage. The inhibitors examined were amsacrine, teniposide, etoposide, and novobiocin; only the latter compound was clearly effective in a selective way at nontoxic concentrations, and this was observed specifically in reference to the repair of potentially lethal damage effected by incubation in conditioned medium. These results are another example of differences between the repair of sublethal versus potentially lethal damage that further support distinctions between the two. At a mechanistic level, these and other data suggest that the property of novobiocin that is relevant in the foregoing is its metabolic inhibition of replicative DNA synthesis, a process which may be more important in the repair of potentially lethal damage as opposed to sublethal damage.     

Differential repair of potentially lethal damage in exponentially growing and quiescent 9L cells

The alteration of potentially lethal damage repair by postirradiation treatment with hypertonic saline (0.5 M PBS) was investigated in exponentially growing and quiescent 9L cells in vitro. A single dose of X rays (8.5 Gy) immediately followed by a 30-min treatment with hypertonic PBS at 37 degrees C reduced the survival of exponentially growing 9L cells by a factor of 13-18 compared to survival of irradiated immediately and delayed-plated cells, while the survival of quiescent cells was reduced by only a factor of 5-8. Survival curves confirmed the relative resistance of the quiescent 9L cells versus exponentially growing 9L cells to X rays plus hypertonic treatment. Both the slope and the shoulder of the survival curve were reduced to a greater extent in exponentially growing cells than in the quiescent cells by hypertonic treatment. The response of quiescent cells cannot be explained by either the duration of hypertonic treatment or the redistribution of the cells into G1 phase. We show that quiescent 9L cells can recover from hypertonically induced potentially lethal damage when incubated under conditions which have been found to delay progression through the cell cycle, and postulate that an altered chromatin structure or an enhanced repair capacity of quiescent 9L cells may be responsible for their resistance.     

Exogenous lactate modifies the repair of potentially lethal damage in three human tumor cell lines irradiated in vitro

Lactate is one of several pathophysiological factors accumulating in the micromilieu of tumors under both hypoxic and well-oxygenized conditions, and thus may affect the recovery of irradiated tumor cells in vivo. In the present study, we investigated the effects of postirradiation incubation with exogenous lactate during confluent holding recovery on the repair of potentially lethal damage in three human tumor cell lines. Recovery was either unaffected or enhanced by low concentrations of exogenous lactate (2-5 mM), whereas it was suppressed by higher concentrations (10-50 mM). With high concentrations, survival in all three cell lines was lower at the end of the confluent holding period than at the beginning, yielding recovery ratios of less than 1.0. The effects differed quantitatively among the three tumor cell lines, and between the tumor cells and the normal diploid fibroblasts (AG 1522) studied previously.     

Inhibitors of repair of potentially lethal damage and DNA polymerases also influence the recovery of potentially neoplastic transforming damage in C3H10T-1/2 cells

The effects of aphidicolin and beta Ara A on radiation sensitivity were evaluated in terms of cell killing, recovery, and neoplastic transformation in the C3H10T-1/2 cell system. When cells were held in plateau phase, recovery of potentially lethal damage (PLD) and potentially transforming damage (PTD) occurred. The addition of beta Ara A resulted in reduced PLD recovery for both the survival and neoplastic transformation end points. The addition of aphidicolin did not affect recovery of PLD or PTD. These data show that the inhibition of polymerase alpha by aphidicolin does not affect recovery of damage leading to cell death or neoplastic transformation. However, the inhibition of both polymerase alpha and beta by beta Ara A resulted in inhibition of recovery of damage leading to both cell death and neoplastic transformation. These data indicated that polymerase beta may be involved in both PLD and PTD recovery.     

Changes in repair of potentially lethal damage with culture age in EMT6 cells.

We have investigated the changes in the amplitude of repair of potentially lethal damage (PLD) in EMT6 cells with increasing culture age and determined the delay necessary to achieve this repair. This experimental system presents all intermediaries between the exponential growth type and a plateau with a cell turnover nearly nil. The radiosensitivity was studied by the colony method. When the percentage of surviving cells was tested immediately after irradiation it was observed that their radiosensitivity increased with culture age. This percentage fell only slightly when the cells were tested for viability 6 hours after irradiation. Therefore, the amplitude of repair increases with culture age. Repair was found to terminate 1, 1.75, 3 and 6 hours after irradiation of cultures aged respectively 2, 4, 6 and 9 days. The delay and the amplitude of repair did not vary significantly for cultures of 9, 11 and 13 days.     

Cell-cycle-dependent repair of potentially lethal damage in the XR-1 gamma-ray-sensitive Chinese hamster ovary cell

Repair of potentially lethal damage (PLD) was investigated in a gamma-ray-sensitive Chinese hamster cell mutant, XR-1, and its parent by comparing survival of plateau-phase cells plated immediately after irradiation with cells plated after a delay. Previous work indicated that XR-1 cells are deficient in repair of double-strand DNA breaks and are gamma-ray sensitive in G1 but have near normal sensitivity and repair capacity in late S phase. At irradiation doses from 0 to 1.0 Gy (100 to 10% survival), the delayed- and immediate-plating survival curves of XR-1 cells were identical; however, at doses greater than 1.0 Gy a significant increase in survival was observed when plating was delayed (PLD repair), approaching a 20-fold increase at 8 Gy. Elimination of S-phase cells by [3H]thymidine suicide dramatically increased gamma-ray sensitivity of plateau-phase XR-1 mutant cells and reduced by 600-fold the number of cells capable of PLD repair after a 6-Gy dose. In contrast, elimination of S-phase cells in plateau-phase parental cells did not alter PLD repair. These results suggest that the majority of PLD repair observed in plateau-phase XR-1 cells occurs in S-phase cells while G1 cells perform little PLD repair. In contrast, G1 cells account for the majority of PLD repair in plateau-phase parental cells. Thus, in the XR-1 mutant, a cell's ability to repair PLD seems to depend upon the stage of the cell cycle at which the irradiation is delivered. A possible explanation for these findings is discussed.     

Two forms of potentially lethal damage have similar repair kinetics in plateau- and in log-phase cells

The effect on the survival of X-irradiated Chinese hamster cells (line V79) of two different post-treatments is examined in plateau- and in log-phases of growth. Qualitatively similar results are obtained with cells in both growth phases; that is, similar reductions in survival are effected by post-treatments with hypertonic phosphate buffered saline, and similar increases in survival are effected by post-treatments with conditioned medium. In addition, in both kinds of cells the kinetics of the repair processes are similar even though the kinetics of the two processes differ from each other considerably. While the results indicate that there can be essential differences in the type and/or the pathways of repair of potentially lethal damage, they also illustrate a broader meaning of this term than has been customary. Considered relative to the amount of DNA damage that can be expected to be potentially lethal, it is concluded that the two types of damage that are the subjects of this study represent only small sectors of the total amount of potentially lethal damage.     

TopBP1 is required at mitosis to reduce transmission of DNA damage to G1 daughter cells

Genome integrity is critically dependent on timely DNA replication and accurate chromosome segregation. Replication stress delays replication into G2/M, which in turn impairs proper chromosome segregation and inflicts DNA damage on the daughter cells. Here we show that TopBP1 forms foci upon mitotic entry. In early mitosis, TopBP1 marks sites of and promotes unscheduled DNA synthesis. Moreover, TopBP1 is required for focus formation of the structure-selective nuclease and scaffold protein SLX4 in mitosis. Persistent TopBP1 foci transition into 53BP1 nuclear bodies (NBs) in G1 and precise temporal depletion of TopBP1 just before mitotic entry induced formation of 53BP1 NBs in the next cell cycle, showing that TopBP1 acts to reduce transmission of DNA damage to G1 daughter cells. Based on these results, we propose that TopBP1 maintains genome integrity in mitosis by controlling chromatin recruitment of SLX4 and by facilitating unscheduled DNA synthesis.     

A comparison of chromosome repair kinetics in G(0) and G(1) reveals that enhanced repair fidelity under noncycling conditions accounts for increased potentially lethal damage repair

Potentially lethal damage (PLD) and its repair were studied in confluent human fibroblasts by analyzing the kinetics of chromosome break rejoining and misrejoining in irradiated cells that were either held in noncycling G(0) phase or allowed to enter G(1) phase of the cell cycle immediately after 6 Gy irradiation. Virally mediated premature chromosome condensation (PCC) methods were combined with fluorescence in situ hybridization (FISH) to study chromosomal aberrations in interphase. Flow cytometry revealed that the vast majority of cells had not yet entered S phase 15 h after release from G(0). By this time some 95% of initially produced prematurely condensed chromosome breaks had rejoined, indicating that most repair processes occurred during G(1). The rejoining kinetics of prematurely condensed chromosome breaks was similar for each culture condition. However, under noncycling conditions misrepair peaked at 0.55 exchanges per cell, while under cycling conditions (G(1)) it peaked at 1.1 exchanges per cell. At 12 h postirradiation, complex-type exchanges were sevenfold more abundant for cycling cells (G(1)) than for noncycling cells (G(0)). Since most repair in G(0)/G(1) occurs via the non-homologous end-joining (NHEJ) process, increased PLD repair may result from improved cell cycle-specific rejoining fidelity of the NHEJ pathway.