Radiation response of mouse lymphoid and myeloid cell lines. Part II. Apoptotic death is shown by all lines examined

Effect of the insulin-like growth factor I receptor on ionizing radiation-induced cell death in mouse embryo fibroblasts

We have investigated the effect of the insulin-like growth factor I receptor (IGF-IR) on ionizing radiation (IR)-induced cell death using the following two mouse embryo fibroblast cell lines: (i) R- cells with a null mutation of the IGF-IR gene, therefore expressing no endogenous IGF-IR; (ii) R+ cells derived from R- cells, a stable transfectant overexpressing the human IGF-IR. Numbers of R- cells began to detach from dishes and float into the medium about 48 h after 10 Gy of X-irradiation. Internucleosomal DNA fragmentation detected by agarose gel electrophoresis, which is characteristic of apoptosis, was observed in the floating R- cells, but not in the attached cells. Unexpectedly, morphological analysis of the floating cells 72 h after irradiation revealed that only about half of them showed apoptotic death and the rest showed a nonapoptotic, presumably necrotic, one. On the other hand, R+ cells retained more than 90% viability even 4 days after irradiation, and very few floating cells were observed. The G2 arrest was induced in both cell lines following irradiation and G2/M fractions similarly returned to normal levels by around 20 h after irradiation, indicating that the cell death which appeared thereafter in R- cells is mediated through mitosis. Significant induction of p53 following irradiation was not detected by Western blot analysis in either R- or R+ cells. Collectively, these results demonstrate that signal transduction pathways originating from the IGF-IR may be involved in preventing IR-induced apoptosis and necrosis without affecting cell cycle arrest or p53 pathways.

Radiation-induced apoptosis in different pH environments in vitro

PURPOSE

The effect of environmental pH on the radiation-induced apoptosis in tumor cells in vitro was investigated.

METHODS AND MATERIALS

Mammary adenocarcinoma cells of A/J mice (SCK cells) were irradiated with gamma-rays using a 137Cs irradiator and incubated in media of different pHs. After incubation at 37 degrees C for 24-120 h the extent of apoptosis was determined using agarose gel electrophoresis, TdT-mediated dUTP-biotin nick end labeling (TUNEL) staining, flow cytometry, and release of 3H from 3H-thymidine labeled cells. The clonogenicity of the cells irradiated in different pH medium was determined, and the progression of cells through the cell cycle after irradiation in different pHs was also determined with flow cytometry.

RESULTS

Irradiation with 2-12 Gy of gamma-rays induced apoptosis in SCK cells in pH 7.5 medium within 48 h as judged from the results of four different assays mentioned. Radiation-induced apoptosis declined as the medium pH was lowered from 7.5 to 6.4. Specifically, the radiation-induced degradation of DNA including the early DNA breaks, as determined with the TUNEL method, progressively declined as the medium pH was lowered so that little DNA fragmentation occurred 48 h after irradiation with 12 Gy in pH 6.6 medium. When the cells were irradiated and incubated for 48 h in pH 6.6 medium and the medium was replaced with pH 7.5 medium, DNA fragmentation promptly occurred. DNA fragmentation also occurred even in pH 6.6 medium when the cells were irradiated and maintained in pH 7.5 medium for 8 h or longer post-irradiation before incubation in pH 6.6 medium. The radiation-induced G2 arrest in pH 6.6 medium lasted markedly longer than that in pH 7.5 medium.

CONCLUSION

Radiation-induced apoptosis in SCK cells in vitro is reversibly suppressed in an acidic environment. Taking the results of four different assays together, it was concluded that early step(s) in the apoptotic pathway, probably the DNA break or upstream of DNA break, is reversibly halted by an acidic environment in irradiated cells. Radiation-induced G2 arrest is prolonged in an acidic environment indicating that the suppression of radiation-induced apoptosis and prolongation of radiation-induced G2 arrest in an acidic environment are related.

Apoptosis and mitotic cell death: their relative contributions to normal-tissue and tumour radiation response

The target-cell theory of tissue responses is reviewed with reference to the radiosensitivity of proposed target cells in bone marrow, intestine, epidermis, and spermatogenesis. The difficulties in precisely identifying target cells using histological/cell marker criteria, and hence determining the role of their mode of death in tissue responses, are being circumvented to some extent by the recent use of mice deficient in gene products required for radiation-induced apoptosis. In this case cell death results from 'mitotic cell death' and e.g. in the case of p53, any remaining p53-independent apoptosis. In the p53 null mouse, cell survival levels are increased in bone marrow and intestine but decreased in the testis. Different interpretations, based on the lack of p53-dependent apoptosis or the lack of a permanently induced G1-arrest in the case of marrow fibroblasts, can be applied to the results for different cell types. Hence both apoptosis and mitotic cell death can variously be involved as contributing to target-cell sensitivity and hence to early reactions in these tissues after irradiation. It is still unclear whether, or how, the mode of cell death (apoptotic versus mitotic) determines the radiosensitivity and response of tumours. In experimental tumours, the levels of radiation-induced apoptosis have been shown to correlate both with the in vivo response to radiation and the degree of spontaneous apoptosis in the tumours. Measurements of spontaneous apoptosis in human tumours, however, have yielded conflicting data with high apoptotic levels significantly correlating with both good and poor prognosis in different studies. There is one report of a lack of relationship between intrinsic radiosensitivity and spontaneous apoptosis in cervical cancers. In contrast several studies have reported correlations between apoptosis levels and the degree of tumour cell proliferation. Tumour hypoxia has also been shown to increase apoptosis. These data suggest that tumour apoptosis may be a reflection of intrinsic radiosensitivity, tumour cell proliferation and tumour hypoxia. Its relative importance will probably be tumour type, size and stage related.

Rapid assay of intrinsic radiosensitivity based on apoptosis in human CD4 and CD8 T-lymphocytes

PURPOSE

An assay for radiosensitivity has numerous applications in the clinic. Avoidance of acute responses, prediction of normal tissue toxicity, and individualization of patient radiotherapy are included among these. We have developed a rapid assay (about 24 h) able to predict intrinsic radiosensitivity of CD4 and CD8 T-lymphocytes based on radiation-induced apoptosis.

METHODS AND MATERIALS

Fresh blood samples (1-2 ml in heparinized tubes) were irradiated with 0-, 2-, and 8-Gy X rays at a dose rate of approximately 3 Gy/min. Following irradiation, the cells were collected and prepared for flow-cytometric analysis and cell sorting. In conjunction with the CellQuest software available with the FACSVantage cell sorter (Becton-Dickinson), two T-lymphocyte types were analyzed on the basis of their cell-specific antigens (CD4 and CD8), and DNA was stained with DAPI. Following the separation of these cell types, radiation-induced cell death was assessed. Cytotoxicity was characterized by gradual degradation of internucleosomal DNA which results in a sub-G1 peak on the DNA histogram, and by the associated loss of surface antigens causing an intermediate positive peak in the antibody histogram. Using the assay, we investigated the interdonor variation in a cohort of 45 healthy adult blood donors and 5 children [one had immunodeficiency, centromeric instability, and facial anomalies syndrome (ICF), and one had ataxia telangiectasia (AT)]. Intradonor variation was assessed with 10 different experiments from a single donor.

RESULTS

CD4 and CD8 T-lymphocyte radiosensitivities were correlated (r = 0.63 and 0.65 for 2 and 8 Gy, respectively) in 45 adult donors. Both for CD4 and CD8 cells, 2 and 8 Gy irradiation responses showed a good correlation (r = 0.77 for both). Interdonor variation was significantly higher than intradonor variation (p < 0.0005) for all CD4 and CD8 data. We observed a decrease in the antigen fluorescence of dying cells, a phenomenon referred to as antigen-ebb. Antigen-ebb was clearly observed in both cell types, and correlated significantly with cytotoxicity. A trend was observed between radiosensitivity and donor age, but there was no correlation for gender. Blood from a 4-year-old girl presenting with ICF demonstrated compromised radiation-induced cytotoxicity in her CD4 T-lymphocytes, and an 11-year-old boy presenting with AT demonstrated compromised radiation-induced cytotoxicity in both his CD4 and CD8 T-lymphocytes.

CONCLUSION

We conclude that the assay provides a rapid means of determining radiosensitivity, can discriminate differences in radiation-induced cytotoxicity between individuals, and can be used as a rapid screen for genetically hypersensitive patients. Antigen-ebb offers interesting possibilities for molecular biological investigations, permitting characterization and isolation of abnormal but vital cells in the absence of clastogenic agents.

Cell killing by the novel imidazoacridinone antineoplastic agent, C-1311, is inhibited at high concentrations coincident with dose-differentiated cell cycle perturbation

We have studied the actions of C-1311, an imidazoacridinone analogue with potent in vivo antitumour activity, against a human tumour line (HeLa S3), in an examination of the events associated with the lethality of this agent. Continuous exposures (24 h) induced complete G2 arrest, although the concentration range of this effect was narrow, with elevation of the drug level inducing additional and increasing impediment to S-phase transit. Acute treatments (3 h) revealed that cells exposed to drug levels, which first induced persistent G2 arrest (0.5 microgram ml-1), subsequently died from this compartment, while doses exceeding these levels (1.0 microgram ml-1), paradoxically, did not cause the same extensive cell death. We explain our findings on the proposition that this particular mode of cell death is dependent upon inappropriate activation of the primed mitotic machinery-specifically the hyperphosphorylated p34cdc2/cyclin B complex-assembled within G2, but that impediment to genomic replication at higher doses inhibits assembly of this complex, and hence prevents cell death. Our results demonstrate that high dose does not necessarily correlate with increased cell death, while at the same time providing further evidence for the importance of events normally associated with the G2/M transition in DNA damage-induced tumour cell death.

Radiation induced apoptosis

The response to ionising radiation, in terms of level of cell killing, depends on a number of factors that may be grouped into those that are genetically controlled, radiation quality and dosage, and environmental factors. There is a range of genetically controlled cellular properties such as stage of differentiation, mutations in specific genes (such as p53 and bcl-2) and stage of transformation that will determine the ability of the target cell to enter apoptosis. The so-called normal cells, are usually more radiosensitive and the majority of the cell population will enter into an apoptotic death. However, in response to high doses of ionising radiation and complex DNA damage as produced by high-LET radiation, an increased fraction of these cells will die by necrosis. There are several examples of environmental factors with relevance for the combined action of radiation and xenobiotics on carcinogenesis and in tumour therapy. In the case of normal cells, agents such as growth factors and tumour promoters, may decrease radiosensitivity. For certain type of tumour cells, radiation sensitivity can be increased in the presence of agents such as hormones, and the cells may die an apoptotic death. Removal of heavily compromised cells is essential to prevent a potential spreading of mutated clones. However, if apoptosis is inhibited (e.g., by tumour promoter), an increased fraction of damaged cells carrying genotoxic lesions may survive. This would significantly increase the risk of proliferation of precancerous cells. As discussed above, it is probably incorrect to make predictions about relative radiosensitivity based solely on mode of death. Intrinsic characteristics deriving from the cell type of origin of a line may be more important in determining radiosensitivity. The rapidly increasing knowledge about the process of radiation induced apoptosis has opened new frontiers in radiation biology, genetic toxicology, and cancer therapy and strongly motivates further research in this field.

A role for apoptosis in the toxicity and mutagenicity of bleomycin in AHH-1 tk+/- human lymphoblastoid cells

The chromosomal mutagen, bleomycin, is also noted for its toxic properties, although the mechanism of cell death is not fully understood. In order to determine if cell death occurred by apoptosis or necrosis, AHH-1 tk+/- cells were exposed to bleomycin and the percentage of viable, apoptotic and necrotic cells quantified by flow cytometry. Logistic regression analysis indicated that the primary manner of cell death was through the apoptosis pathways, that apoptosis was delayed, and that apoptosis was accompanied by an arrest in the G2 phase of the cell cycle. Once apoptosis was established as a mechanism for cell death, the efficiency with which these pathways removed damaged cells from the population was evaluated with the use of specific-locus mutation assays (tk and hprt) as indicators of cells with DNA damage that maintained viability and clonogenicity. Linear regression analysis detected a significant, concentration-dependent increase in the numbers of TFTr clones with the slow-growth phenotype. This suggests that a proportion of cells with bleomycin-induced DNA damage did not undergo cell death by apoptosis and that apoptosis, a mechanism for the destruction of damaged cells, is not fully efficient in the AHH-1 tk +/- cell line.

Apoptosis--molecular mechanisms and biomedical implications

Apoptosis is a distinct form of cell death of importance in tissue development and homeostasis and in several diseases. This review summarizes current knowledge about the regulation and molecular mechanisms of apoptosis and discusses the potential role of disregulated apoptosis in several major diseases. Finally, we speculate that modulation of apoptosis may be a target in future drug therapy.

Radiosensitization of HL-60 human leukaemia cells by bryostatin-1 in the absence of increased DNA fragmentation or apoptotic cell death

Ionizing radiation produced a dose-dependent reduction in the proliferative capacity of HL-60 human promyelocytic leukaemia cells. A small percentage of the cell population demonstrated morphological evidence of apoptosis at 24h following radiation doses of > or = 5 Gy (i.e. 8% at 5 Gy and 16% at 10 Gy respectively) and produced a laddered oligonucleosomal pattern of DNA fragments by static-field gel electrophoresis. The antiproliferative effects of 1 and 2.5 Gy ionizing radiation were significantly enhanced by preincubating cells with bryostatin-1 at a concentration (10 nM) and time frame (24h) associated with down-regulation of total cellular protein kinase C (PKC) activity. Potentiation by bryostatin-1 of the radiation effect on proliferation was not associated with a concomitant increase in internucleosomal DNA fragmentation, in the fraction of cells exhibiting apoptotic morphology, or in the extent of radiation-induced single- or double-strand breaks in bulk DNA. Staurosporine, a potent but nonspecific inhibitor of PKC, was ineffective in altering the radiosensitivity of HL-60 cells or the degree of DNA fragmentation induced by ionizing radiation. These findings indicate that bryostatin 1 increases the sensitivity of human myeloid leukaemic cells to low radiation doses without enhancing DNA fragmentation or apoptosis, and that this capacity may involve factors other than, or in addition to, down-modulation of PKC activity.

Cell cycle traverse in AHH-1 tk +/- human lymphoblastoid cells exposed to the chromosomal mutagen, m-amsa

AHH-1 tk +/- cells were exposed to the chemotherapeutic agent, m-amsa, both in complete medium and in medium without serum, subcultured in complete medium, and the effect on the traverse of the cell cycle determined by flow cytometric analysis of bromodeoxyuridine (BrdUrd)-labeled DNA. After exposure to m-amsa (day 0), the percentage of S-phase cells increased significantly (P < 0.0017) with increasing concentration. Cells also accumulated in G2/M as evidenced by the significant (P < 0.0026), concentration-dependent increase in the percentage of cells detected within this phase. Serum deprivation during exposure resulted in significantly (P = 0.024) more cells in S-phase than in cultures exposed to m-amsa in complete medium. After three days in culture, a significant (P = 0.0001) accumulation of cells in G2/M was present; the percentage of cells in G2/M did not differ significantly (P = 0.148) in cultures exposed to m-amsa in complete medium or in serum-free medium. However, a significant (P < 0.001) loss of S-phase cells was found in cultures exposed without serum. At day 7, no significant concentration effects were detected (GO/G1, P = 0.6026; S-phase, P = 0.9773; G2/M, P = 0.8401). These results demonstrate that exposure to m-amsa perturbs the traverse of the cell cycle, initially by inhibiting the completion of S-phase and followed by an accumulation of cells in G2/M. In addition, exposure to m-amsa under conditions of serum deprivation results in an increased percentage of cells in the initial S-phase after exposure, the loss of S-phase cells from the culture after three days, and the appearance of subdiploid peak, consistent with cells undergoing apoptosis.

Radiation-induced apoptosis: relevance to radiotherapy

Radiation-induced apoptosis is reviewed in terms of: (a) the identification of apoptotic and necrotic cells, (b) observations in vitro and in vivo of radiation-induced apoptosis, (c) genes controlling apoptosis, (d) evidence that the target may be the plasma membrane or nuclear DNA, (e) quantitative comparisons of apoptotic death and reproductive (clonogenic) death, (f) the importance of radiation-induced apoptosis in radiotherapy, and (g) studies of radiation-induced apoptosis that are needed. High priority should be placed on determining the molecular pathways that are important in the expression and modulation of radiation-induced apoptosis. Specifically, the events that modulate the apoptosis that occurs in interphase before the cell can divide should be distinguished from the events before division that modulate the misrepair of DNA damage, that results in chromosomal aberrations observed in mitotic cells, which in turn cause the progeny of the dividing cell with aberrations to die by either apoptosis or necrosis. Then, molecular events that determine whether a cell that divides with or without a chromosomal aberration will produce progeny that apoptose or necrose need to be identified. These considerations are important for determining how modulation of radiation-induced apoptosis will affect the ultimate clonogenic survival, and possibly genomic instability in the surviving progeny.

Comparative studies of induction and repair of DNA double-strand breaks in X-irradiated alveolar macrophages and resting peripheral blood lymphocytes using constant-field gel electrophoresis

Induction and repair of X-ray-induced DNA double-strand breaks (dsbs) was compared for normal broncho-alveolar macrophages and human peripheral blood lymphocytes, using CHO cells as a reference cell model. The cells, upon their separation, were processed in a similar manner. After X-irradiation, cell lysis and proteinase K treatment, the DNA samples were subjected to constant-field gel electrophoresis (CFGE) followed by fluorimetric densitometry for quantification of released DNA. Induction of dsbs after X-ray doses of 5-100 Gy was found to show no gross differences for all cell systems used. Repair of dsbs was studied after X-ray dose of 60 Gy for up to 24 h after irradiation. The repair curves obtained proved to be similar for bronchoalveolar macrophages and CHO cells (97% of all dsbs rejoined after 24 h). However, in blood lymphocytes from normal subjects and from bone marrow recipients, dsb repair proceeded rapidly only for 0.5-1 h post-irradiation, being followed by the gradual degradation of DNA at longer intervals. The kinetics of DNA degradation correlated with cytological features of pyknosis and necrosis.

Radiation-induced apoptosis in human sarcoma and glioma cell lines

Six human soft-tissue sarcoma and 14 glioma cell lines, exhibiting considerable differences in radioresponsiveness and histological grade of differentiation of the parental tumour, were examined with respect to apoptosis development after irradiation with 60Co gamma-rays. After test doses of 6 and 25 Gy, significant changes characteristic of apoptosis occurring within 6 to 30 hr were exhibited by only 2 differentiated sarcoma cell lines, EL7 and ESS2. The characteristic internucleosomal fragmentation of DNA was detected as early as 6 hr after exposure of subconfluent monolayer cultures to 6 Gy. It was limited to cells that had detached from the culture plate, whereas adherent cells showed random degradation of DNA, namely after higher doses (25Gy) or longer incubation times (30 hr). As assessed by fluorescence microscopy of unfixed cultures stained with Hoechst 33342 and propidium iodide, the proportion of cells showing apoptotic bodies in non-irradiated controls was < 0.1% and 0.3% for EL7 and ESS2, respectively. The dose-response relationship for apoptosis was determined at 9 hr post-irradiation. After 2 Gy, the percentage of apoptotic cells was elevated to 3.4% in EL7 and 4.5% in ESS2 cultures. Saturation was obtained above 6 Gy, with 8.4% apoptosis in EL7 and 15% in ESS2 after 25 Gy. Taken together, rapid ionizing-radiation-induced apoptosis seems to be limited to a subgroup of sarcomas and is unlikely to occur in gliomas.

Radiation-induced apoptotic cell death in human gastric epithelial tumour cells; correlation between mitotic death and apoptosis

The mode of cell death in cells undergoing mitotic death after gamma-irradiation was studied in seven human gastric epithelial tumour cell lines and two strains of normal gastric fibroblasts. Apoptotic cells were frequently observed in all tumour lines after irradiation, whereas the two fibroblast strains were quite low in apoptosis frequency. The advent of apoptosis depended on the radiation doses and incubation time. Detailed analysis of one of the carcinoma lines, SH101-P4, revealed that G2-phase arrest was maximum at 12 h postirradiation. The cells began to escape G2 arrest by 24 h. Apoptotic cells began to increase at 12 h postirradiation and became maximal from 72 to 96 h. Apoptosis developed in the G1 phase of the cell cycle subsequent to the irradiation. These results suggest that apoptosis is one of the modes of mitotic death after irradiation.

Increasing the susceptibility of the rat 208F fibroblast cell line to radiation-induced apoptosis does not alter its clonogenic survival dose-response

Recent studies have suggested a correlation between the rate and incidence of apoptosis and the radiation response of particular cell lines. However, we found that increasing the rate of induction of apoptosis in the fibroblast line 208F, by transfecting it with human c-myc, did not lead to a change in its clonogenic survival dose-response for either gamma-irradiation or 125I-induced DNA damage. It was also found that expression of mutant (T24) Ha-ras in the 208F line appeared to decrease the level of apoptosis per mitosis after irradiation and inhibited the formation of nucleosomal ladders, but did not affect either the onset of the morphological features of apoptosis or the clonogenic survival dose-response of the cells to either gamma-irradiation or 125I-induced DNA damage. Our findings suggest that it may be incorrect to make predictions about the radiosensitivity of cells based only on knowledge of their mode of death.

Apoptosis induced by high- and low-LET radiations

Cell death after irradiation occurs by apoptosis in certain cell populations in tissues. The phenomenon also occurs after high linear energy transfer (LET) irradiation, and the relative biological effectiveness (RBE) is 3 to 4 (with respect to low-LET radiation and apoptosis in intestinal crypts) for neutrons with energies of 14 MeV and up to 600 MeV. It is thought that p53 plays a role in the phenomenon, as radiation-induced apoptosis is not observed in p53-null animals.

Correlation of micronucleus and apoptosis assays with reproductive cell death

The relationship between ionizing radiation-induced cell killing and DNA damage measured by the micronucleus and apoptosis assays was determined in three established cell lines (L929, HL-60, and Chang). Irradiation experiments revealed a dose-dependent increase of micronucleated cells until a certain dose was reached. Above this dose no further increase of the micronucleus frequency was observed, but in HL-60 and Chang cells additional DNA fragmentation was detected by morphological criteria, characteristic of apoptosis. This change was detected at different doses for the three cell lines examined, suggesting the existence of a cell-type-dependent upper limit for the employment of the micronucleus assay. However, the sum of both kinds of cellular DNA damage (e.g. micronucleation and morphological-like apoptosis) led to a significant cell-type-independent correlation with cell survival, even above the dose where micronuclei levels saturated. Therefore, a total cell damage assay, involving the inclusion of micronuclei and morphological-like apoptotic events, should be considered when evaluating the use of a predictor assay for ionizing radiation-induced cell killing, especially in conditions when apoptosis (-like) processes may occur.

DNA damage triggers a prolonged p53-dependent G1 arrest and long-term induction of Cip1 in normal human fibroblasts

The tumor suppressor p53 is a cell cycle checkpoint protein that contributes to the preservation of genetic stability by mediating either a G1 arrest or apoptosis in response to DNA damage. Recent reports suggest that p53 causes growth arrest through transcriptional activation of the cyclin-dependent kinase (Cdk)-inhibitor Cip1. Here, we characterize the p53-dependent G1 arrest in several normal human diploid fibroblast (NDF) strains and p53-deficient cell lines treated with 0.1-6 Gy gamma radiation. DNA damage and cell cycle progression analyses showed that NDF entered a prolonged arrest state resembling senescence, even at low doses of radiation. This contrasts with the view that p53 ensures genetic stability by inducing a transient arrest to enable repair of DNA damage, as reported for some myeloid leukemia lines. Gamma radiation administered in early to mid-, but not late, G1 induced the arrest, suggesting that the p53 checkpoint is only active in G1 until cells commit to enter S phase at the G1 restriction point. A log-linear plot of the fraction of irradiated G0 cells able to enter S phase as a function of dose is consistent with single-hit kinetics. Cytogenetic analyses combined with radiation dosage data indicate that only one or a small number of unrepaired DNA breaks may be sufficient to cause arrest. The arrest also correlated with long-term elevations of p53 protein, Cip1 mRNA, and Cip1 protein. We propose that p53 helps maintain genetic stability in NDF by mediating a permanent cell cycle arrest through long-term induction of Cip1 when low amounts of unrepaired DNA damage are present in G1 before the restriction point.

Phorbol esters can protect mouse pre-T cell lines from radiation-induced rapid interphase apoptosis

Protein kinase C stimulators were found to increase the radioresistance of the mouse pre-T cell-derived line ST4. Increased resistance to gamma-ray-induced killing could be produced by addition of 10 nM phorbol 12-myristate 13-acetate (PMA) to ST4 cultures either immediately before or up to 2 h after irradiation. Following PMA treatment, ST4 changed from a cell line that underwent rapid interphase apoptosis (i.e. DNA degradation and morphology characteristic of apoptosis were evident 2-3 h after irradiation) to a line that continued to cycle after irradiation and began to die by apoptosis after completing mitosis. Associated with these PMA-induced changes, the D0 of ST4 cells increased from 7.7 +/- 0.7 to 18.8 +/- 2.7 125I decays. Another mouse pre-T cell-derived line, ST1, which is susceptible to radiation-induced rapid interphase apoptosis, also showed radioprotection after PMA treatment. In contrast, PMA increased the radiosensitivity of the pre-T cell-derived W7 line, which undergoes radiation-induced delayed interphase apoptosis (i.e. death following blockage in G2 phase). PMA had no effect on the radiosensitivity of a pre-B cell-derived line, A8, which undergoes rapid interphase apoptosis, and on a pre-T cell-derived line, W22, which undergoes apoptosis after mitosis. These results suggest that the radiomodifying ability of PMA treatment is dependent upon the cell death pathway induced by irradiation and upon the cell lineage.

Radiation response of mouse lymphoid and myeloid cell lines. Part I. Sensitivity to killing by ionizing radiation, rate of loss of viability, and cell type of origin

The sensitivity of 10 mouse lymphoid or myeloid cell lines to gamma-ray- and DNA-associated 125I-decay-induced clonogenic cell killing have been compared with their rate of loss of viability (membrane integrity) and with their putative cell type of origin. The pseudodiploid haematopoietic cell lines showed D0 values for 125I-induced DNA double-strand breakage (dsb) that ranged from 7.7 +/- 0.7 to 40.8 +/- 2.8 decays. These lines generally appeared to be more sensitive to killing by radiation-induced DNA dsb than are fibroblast-like cell lines. The increased sensitivity of haematopoietic cell lines to killing by DNA dsb may be related to their mode of death (apoptosis versus necrosis). Mode of cell death may thus be an important factor in determining the 'inherent radiosensitivity' of normal cells/tissues. Haematopoietic cell lines that undergo rapid interphase apoptotic death showed extreme sensitivity to DNA dsb. The latter cell lines were found to have derived from immature lymphoid cells, and it is speculated that their high radiosensitivity might reflect the action of a mechanism that normally eliminates cells containing illegitimate V(D)J recombinase-induced DNA dsb.

Radiation response of mouse lymphoid and myeloid cell lines. Part III. Different signals can lead to apoptosis and may influence sensitivity to killing by DNA double-strand breakage

We have examined the timing of gamma-irradiation-induced death in relation to cell cycle progression using a panel of mouse lymphoid or myeloid cell lines. Death was found to occur immediately after irradiation ('rapid interphase' death), or after arrest in G2 phase ('delayed interphase' death). In part II of this series of papers we demonstrated the occurrence of radiation-induced apoptosis in all these cell lines. This suggests that different signals can lead to apoptosis in these cell lines. DNA double-strand breakage appeared to directly stimulate the destruction of cell lines susceptible to rapid interphase death, whilst the signal for delayed interphase and mitotic death, whilst the signal for delayed interphase and mitotic death appeared to be chromosomal aberrations. Several of the cell lines showed different timing of death dependent upon the radiation dose used. These differences in the timing of radiation-induced death are shown to be useful indicators of the relative radiosensitivity of haematopoietic cell lines.