Induction of oncogenic transformation by low doses of X rays and dose-rate effect

Golden hamster embryo cells were used to study morphological transformation induced by low doses of X rays at different dose rates. X irradiation at lower dose rates was less effective in cell killing and induction of transformation than at higher dose rates. The general shapes of induction curves of transformants were almost the same at all dose rates. At shoulder doses (1 to 150 R), the transformation frequencies increased steeply with increasing dose at all dose rates. At doses higher than 150 R survivals declined exponentially, but the frequencies of transformants increased only slightly. However, irradiation at higher dose rates was more effective in induction of transformants than that at lower dose rates. We conclude that transformational damage introduced at a low dose rate, as well as sublethal damage, may be repaired during low-dose-rate irradiation, but transformational damage may be different from sublethal damage.     

Dose fractionation effects in plateau-phase cultures of C3H 10T1/2 cells and their transformed counterparts

A comparison of gamma-ray dose fractionation effects was made using plateau-phase cultures of C3H 10T1/2 cells and their transformed counterparts in an attempt to simulate basically similar populations of cells that differ primarily in their turnover rates. The status of cell populations with respect to their turnover rates may be an important factor influencing dose fractionation effects in early- and late-responding tissues. In this cell culture system, the rate of cell turnover was approximately three times higher for the plateau-phase transformed cultures. While the single acute dose survival curves for log-phase cells were indistinguishable, there were significant differences between the survival curves for plateau-phase cultures of the two cell types. These differences were qualitatively similar to the differences recently postulated for the survival of target cells governing early and late tissue responses. Both cell lines had a similar capacity for repair of sublethal damage, but untransformed cells had a much greater capacity to repair potentially lethal damage in plateau phase. Further, untransformed plateau-phase cultures were much more sensitive to a radiation-induced G1 (or G0 to G1) delay than transformed cultures. Multifraction survival curves were determined for both cell lines for doses per fraction ranging from 9.0 to 0.8 Gy, and from these isoeffect curves of log total dose versus dose per fraction were derived. The isoeffect curve for the slowly cycling, untransformed cells was found to be appreciably steeper than that for the more rapidly cycling transformed cells, a finding consistent with previously reported differences in dose fractionation isoeffect curves for early- and late-responding tissues in vivo.     

Effects of continuous low dose-rate irradiation: computer simulations

The effects of continuous low dose-rate irradiation are studied with a computer model that incorporates cell kinetics and the accumulation and repair of radiation damage. This theoretical approach independently explores the effects on survival curves of a phase block, inherited damage and proliferation by dying cells. The computer model is a Monte Carlo simulation which follows the evolution in time of the family trees of a growing cell population under continuous irradiation. The model uses as input the measured phase-specific survival curves for acute exposures and the cell kinetic parameters to generate survival curves for continuous low dose-rate irradiations. Cell survival curves for Chinese hamster lung cells (V79) for dose rates ranging from 15 to 500 cGy/h have been generated using various model assumptions. The model shows that for these cells a G2 block will maximize cell killing for an optimum dose rate near 75 cGy/h. The effect on survival curves of inherited damage, as well as that of the proliferation by dying cells, is shown to increase monotonically with decreasing dose rates, and to be quite large at low dose rates.     

Effects of Continuous Low Dose-Rate Irradiation: Computer Simulations

Abstract. The effects of continuous low dose-rate irradiation are studied with a computer model that incorporates cell kinetics and the accumulation and repair of radiation damage. This theoretical approach independently explores the effects on survival curves of a phase block, inherited damage and proliferation by dying cells. the computer model is a Monte Carlo simulation which follows the evolution in time of the family trees of a growing cell population under continuous irradiation. the model uses as input the measured phase-specific survival curves for acute exposures and the cell kinetic parameters to generate survival curves for continous low dose-rate irradiations. Cell survival curves for Chinese hamster lung cells (V79) for dose rates ranging from 15 to 500 cGy/h have been generated using various model assumptions. the model shows that for these cells a G₂ block will maximize cell killing for an optimum dose rate near 75 cGy/h. the effect on survival curves of inherited damage, as well as that of the proliferation by dying cells, is shown to increase monotonically with decreasing dose rates, and to be quite large at low dose rates.     

DNA repair, DNA synthesis and cell cycle delay in human lymphoblastoid cells differentially sensitive to the cytotoxic effects of nitrogen mustard

Two cloned human lymphoblastoid cell lines, Raji and TK6, differ in their sensitivity to the cytotoxic effects of nitrogen mustard (HN2). Raji cells exhibit a biphasic response with an initial D value of 0.06 microgram/ml and a final slope of 0.25 microgram/ml. TK6 cells were considerably more sensitive, D0 value 0.02 microgram/ml. Dose-response relationships for delay in cell cycle progression were measured using flow cytometry. Delay in S-phase traverse was concentration-dependent in both cell lines, and at a given concentration was 2-fold greater in TK6 than in Raji. Numbers of crosslinks (determined by alkaline elution) increased linearly with increasing HN2 concentration and were approximately 2-fold higher in TK6 than in Raji. At equal levels of DNA crosslinks, rates of removal were similar in both cell lines. Inhibition of [3H]TdR uptake was concentration-dependent and the extent of inhibition was similar in both cell lines. Recovery from HN2-induced inhibition of cell cycle progression markedly preceded recovery from inhibition of [3H]TdR incorporation suggesting that nucleotide pools are markedly perturbed in HN2-treated cells. The difference in sensitivity of these two cell lines cannot be adequately explained by differences in amounts of initial DNA damage, rates of repair, differential S-phase delay or rate of loss of DNA crosslinks.     

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.     

Radiation response of haematopoietic cell lines of human origin

Six human haematopoietic cell lines, five of leukaemic origin, including cells with myeloid, lymphoid and undifferentiated phenotype have been studied with respect to radiation response. The intrinsic radiosensitivity of the cells varied widely, the D0s ranging from 0.53 to 1.39 Gy. Five of the cell lines showed some capacity to accumulate sublethal damage; in three of these, enhanced survival was demonstrated in split-dose experiments. One cell line (HL-60) was anomalous in that although little accumulation of sublethal damage was demonstrable, survival was enhanced by fractionation of the dose. Five of the six cell lines studied were of leukaemic origin. The results support the belief that, in contrast to the almost constant radiosensitivity of normal haematopoietic cell progenitors, leukaemic cell progenitors may show a wide range of radiosensitivites.     

Effect of fractionation and rate of radiation dose on human leukemic cells, HL-60

The capacity of HL-60 cells, human acute promyelocytic leukemic cells established in culture, to repair sublethal radiation damage was estimated from the response of the cells to fractionated irradiation or to a single irradiation at different dose rates. The HL-60 cells grown as a suspension culture in RPMI 1640 medium supplemented with 10% calf serum and antibiotics showed a cloning efficiency of about 0.46 in an agar culture bed. After exposure of cells to a single dose of X rays at a dose rate of 78 rad/min, the survival curve was characterized by n = 2.5, Dq = 80 rad, and D0 = 83.2 rad. Split-dose studies demonstrated that the cells were able to repair a substantial portion of sublethal radiation damage in 2 hr. The response of the cells to irradiation at different dose rates decreased with a decrease in the dose rates, which could be attributed to repair of sublethal radiation damage. The radiation response of leukemic cells is only one of the many factors which affect the clinical outcome of total-body irradiation (TBI) followed by bone marrow transplantation. Nevertheless, the possibility that some of the malignant hemopoietic cells, if not all, may possess a substantial capacity to repair sublethal radiation damage should not be underestimated in planning total-body irradiation followed by bone marrow transplantation.     

Differential effects in cells exposed to ultra-short, high intensity electric fields: cell survival, DNA damage, and cell cycle analysis

High power, nanosecond pulsed electric field (nsPEF) effects have been focused on bacterial decontamination, but the impact on mammalian cells is now being revealed. During nsPEF applications, electrical pulses of 10, 60 or 300 ns durations were applied to cells using electric field amplitudes as high as 300 kV/cm. Because of the ultra-short pulse durations, the energy transferred to cells is negligible, and only non-thermal effects are observed. We investigated the genotoxicity of nsPEF on adherent and non-adherent cell lines including 10 human lines and one mouse cell line with different origin and growth characteristics. We present data examining the effects of nsPEF exposure on cell survival assessed by clonogenic formation or live cell count; DNA damage determined by the comet assay and chromosome aberrations; and cell cycle parameters by measuring the mitotic indices of exposed cells. Using each of these indicators, we observed differential effects among cell types with non-adherent cells being more sensitive to the genotoxic effects of nsPEF exposures than adherent cells. Non-adherent cultures showed a rapid decrease in cell viability (90%), induction of DNA damage, and a decrease in the number of cells reaching mitosis after one 60 ns pulse with an electric field intensity of 60 kV/cm. These effects were not observed in cells grown as adherent cultures, with the exception of the mouse 3T3 cell line, which showed survival characteristics similar to non-adherent cultures. These data suggest that nsPEF genotoxicity may be cell type specific, and therefore have potential applications in the selective removal of one cell type from another, for example, in diseased states.     

A comparison of gamma and neutron irradiation on Raji cells: effects on DNA damage, repair, cell cycle distribution and lethality.

The Comet assay (microgel electrophoresis) was used to study DNA damage in Raji cells, a B-lymphoblastoid cell line, after treatment with different doses of neutrons (0.5 to 16 Gy) or gamma rays (1.4 to 44.8 Gy). A better growth recovery was observed in cells after gamma-ray treatments compared with neutron treatments. The relative biological effectiveness (RBE) of neutron in cell killing was determined to be 2.5. Initially, the number of damaged cells per unit dose was approximately the same after neutron and gamma-ray irradiation. One hour after treatment, however, the number of normal cells per unit dose was much lower for neutrons than for gamma rays, suggesting a more efficient initial repair for gamma rays. Twenty-four hours after treatment, the numbers of damaged cells per unit dose of neutrons or gamma rays were again at comparable level. Cell cycle kinetic studies showed a strong G2/M arrest at equivalent unit dose (neutrons up to 8 Gy; gamma rays up to 5.6 Gy), suggesting a period in cell cycle for DNA repair. However, only cells treated with low doses (up to 2 Gy) seemed to be capable of returning into normal cell cycle within 4 days. For the highest dose of neutrons, decline in the number of normal cells seen at already 3 days after treatment was deeper compared with equivalent unit doses of gamma rays. Our present results support different mechanisms of action by these two irradiations and suggest the generation of locally multiply damaged sites (LMDS) for high linear energy transfer (LET) radiation which are known to be repaired at lower efficiency.     

Apoptosis of non-small-cell lung cancer cell lines after paclitaxel treatment involves the BH3-only proapoptotic protein Bim

A significant variation in susceptibility to paclitaxel-mediated killing was observed among a panel of short-term cultured non-small-cell lung cancer (NSCLC) cell lines. Susceptibility to killing by paclitaxel correlated with expression of the BH3-only protein, Bim, but not with other members of Bcl-2 family. NSCLC cell lines with the highest level of Bim expression are most susceptible to apoptosis induction after paclitaxel treatment. Forced expression of Bim increased paclitaxel-mediated killing of cells expressing an undetectable level of Bim. Conversely, knock down of Bim, but not Bcl-2 expression, decreased the susceptibility of tumor cells to paclitaxel-mediated killing. Similar observations were made using a panel of breast and prostate cancer cell lines. Paclitaxel impairs microtubule function, causes G2/M cell cycle blockade, mitochondria damage, and p53-independent apoptosis. These results established Bim as a critical molecular link between the microtubule poison, paclitaxel, and apoptosis.     

The relationship between chromosomal aberrations, survival and DNA repair in tumour cell lines of differential sensitivity to X-rays and sulphur mustard

A pair of cultured rat lymphosarcoma cell lines (Yoshida) with a pronounced differential sensitivity to killing with sulphur mustard (SM), but with the same sensitivity to X-rays, was examined for chromosome damage and DNA repair replication after treatment with these agents. A pair of mouse lymphoma cell lines (L5178Y) with a differential sensitivity to X-rays was similarly investigated.SM-resistant Yoshida cells suffered much less chromosome damage than sensitive cells in spite of equal alkylation of DNA, RNA and protein in sensitive and resistant cells. The pair of Yoshida cell lines sustained the same amount of chromosome damage after X-irradiation. Much less chromosome damage was observed in the radiation-resistant lymphoma cell line than in the sensitive line after X-irradiation.No differences was found between the pairs of cell lines in their capacities for repair replication after SM or X-ray treatment.Thus, the drug and radiation resistance is accompanied by, and perhaps mediated through, a reduced amount of induced chromosome damage but is not quantitatively related to the capacity for DNA repair replication.Apart from small differences in modal chromosome numbers there are no obvious karyotype differences between the sulphur mustard-sensitive and -resistant Yoshida cells or between the radiation-sensitive and -resistant lymphoma cells.     

艰难梭菌A毒素的细胞致死活性研究

本文报道艰难梭菌Ａ毒素对４种培养细胞的细胞致死活性的探讨。４种培养细胞为Ｖｅｒｏ（非洲绿猴肾细胞）细胞、ＴＰＣ─１（人甲状腺肿瘤细胞）细胞、ＮＩＨ３Ｔ３细胞（小鼠成纤维细胞）及将ｒａｓ癌基因转基因于ＮＩＨ３Ｔ３细胞的ＮＩＨ３Ｔ３ｒａｓ细胞。应用台酚蓝排除能试验、噻唑蓝（ＭＴＳ）比色、细胞膜损害测定试验、荧光显微术观察细胞核的形态变化等测定Ａ毒素细胞致死活性。实验表明：４种培养细胞系对Ａ毒素细胞圆缩化作用的敏感性依次为ＮＩＨ３Ｔ３ｒａｓ,ＴＰＣ─１,Ｖｅｒｏ,ＮＩＨ３Ｔ３细胞。而对Ａ毒素细胞致死活性的敏感性依次为ＴＰＣ─１,ＮＩＨ３Ｔ３,Ｖｅｒｏ,ＮＩＨ３Ｔ３ｒａｓ细胞。从而得知Ａ毒素的细胞致死活性不但依细胞种类不同而不同,而且也不一定与Ａ毒素的细胞圆缩化作用有关。肿瘤细胞ＴＰＣ─１细胞对Ａ毒素致死活性有特殊敏感性。以上结果对探索抗癌新药的研制具有重要意义。     

The radiosensitivity of the chromosomes of the cells of human squamous cell carcinoma cell lines.

Measurement of the radiation sensitivity of chromosomes was used to address the influence of cell cycle distribution and of DNA content and ploidy on radiation responses in seven human squamous cell carcinoma cell lines. The cell lines varied about twofold in DNA content and chromosome number, and the X-ray sensitivities (D0) of the lines ranged from 1.1 to 2.7 Gy. The more resistant cell lines (D0 greater than 1.8 Gy) had faster growth rates and larger proportions of cells in S phase in asynchronous cultures. Aberration frequencies were measured in cells irradiated in G1 and G2 phase. The more resistant lines had fewer induced aberrations in both phases than did sensitive lines, implying that they were more resistant to radiation in both of these cell cycle phases. Therefore, while the larger S-phase population seen in the resistant cell lines probably contributes to the resistant phenotype, it cannot explain all of the intrinsic differences in radiation sensitivity. There was no relationship between DNA content and radiation sensitivity as measured by the cell survival assay or the induction of chromosome aberrations, although cells with larger DNA contents tended to have more chromosome damage per cell at equitoxic doses.     

Growth-phase-dependent response to DNA damage in poly(ADP-ribose) polymerase deficient cell lines: basis for a new hypothesis describing the role of poly(ADP-ribose) polymerase in DNA replication and repair

We have studied the role of poly(ADP-ribose) polymerase in the repair of DNA damage induced by x-ray and N-methyl N-nitro-N-nitrosoguanidine (MNNG) by using V79 chinese hamster cells, and two derivative mutant cell lines, ADPRT54 and ADPRT351, that are deficient in poly(ADP-ribose) polymerase activity. Under exponentially growing conditions these mutant cell lines are hypersensitive to x-irradiation and MNNG compared to their parental V79 cells which could be interpreted to suggest that poly(ADP-ribose) polymerase is involved in the repair of DNA damage. However, the level of DNA strand breaks induced by x-irradiation and MNNG and their rates of repair are similar in all the cell lines, thus suggesting that it may not be the difference in strand break formation or in its rate of repair that is contributing to the enhanced cell killing in exponentially growing poly(ADP-ribose) polymerase deficient cell lines. In contrast, under growth-arrested conditions, all three cell lines become similarly sensitive to both x-irradiation and MNNG, thus suggesting that poly(ADP-ribose) polymerase may not be involved in the repair of DNA damage in growth-arrested cells. These paradoxical results could be interpreted to suggest that poly(ADP-ribose) polymerase is involved in DNA repair in a cell-cycle-dependent fashion, however, it is functionally active throughout the cell cycle. To resolve this dilemma and explain these results and those obtained by many others, we propose that the normal function of poly(ADP-ribose) polymerase is to prevent DNA recombination processes and facilitate DNA ligation.     

Clastogenic effects of methylnitrosourea and ethylnitrosourea on chromosomes from human fibroblast cell lines.

Human fibroblast cell lines were pulse-treated for 1 h with either methylnitrosourea (MNU) or ethylnitrosourea (ENU) at various time intervals before harvesting for chromosome analysis. Cells treated with 1 X 10(-3) M, 5 X 10(-4) M, and 1 X 10(-4) M final concentrations of MNU and ENU during the G2 or M phases of the cell cycle showed a significant increase in chromatid-type abnormalities over controls. Cells exposed to MNU or ENU 23 h before harvest showed some chromosome-type abnormalities, reflecting probable damage induced during the G1 phase of the cell cycle or derived from chromatid damage induced during the previous cell cycle. The mitotic indices and incidences of abnormalities suggested a dose response effect when cells were treated with the two higher concentrations and the three concentrations, respectively, of MNU or ENU. Chromatid abnormalities were observed in MUN and ENU-treated cells from each of four cell lines. From this investigation, it was concluded that MNU and ENU treatment of human diploid cell lines in vitro induced both chromatid and chromosome aberrations. MNU and ENU, both of which had previously been shown to be mutagenic in experimental animals, are, therefore, also considered to be mutagenic at the chromosome level in human fibroblasts grown and treated in cell culture.     

Effects of exposure to low-dose-rate (60)co gamma rays on human tumor cells in vitro

Cells of three asynchronously growing human tumor cell lines, PC3 (human prostate carcinoma), T98G and A7 (human glioblastomas), which have been shown previously to demonstrate low-dose hyper-radiosensitivity to low acute single doses, were irradiated with (60)Co gamma rays at low dose rates (2 cGy-1 Gy h(-1)). Instead of a dose-rate sparing response, these cell lines demonstrated an inverse dose-rate effect on cell survival at dose rates below 1 Gy h(-1), whereby a decrease in dose rate resulted in an increase in cell killing per unit dose. A hyper-radiosensitivity-negative cell line, U373MG, did not demonstrate an inverse dose-rate effect. Analysis of the cell cycle indicated that this inverse dose-rate effect was not due to accumulation of cells in G(2)/M phase or to other cell cycle perturbations. T98G cells in reversible G(1)-phase arrest also showed an inverse dose-rate effect at dose rates below 30 cGy h(-1) but a sparing effect as the dose rate was reduced from 60 to 30 cGy h(-1). We conclude that this inverse dose-rate effect in continuous exposures reflects the hyper-radiosensitivity seen in the same cell lines in response to very small acute single doses.     

Overexpression of human Ku70/Ku80 in rat cells resulting in reduced DSB repair capacity with appropriate increase in cell radiosensitivity but with no effect on cell recovery.

The effect of an overexpression of human Ku70/80 was studied using cells of the rat cell lines Rat-1 and R7080, the latter being transfected with the human cDNAs for Ku70 and Ku80. The overexpression was found to result in a 20% reduction of the DNA-PK activity. The kinetics of DSB repair, which was studied after exposure of the cells to 30 Gy of X rays, was biphasic and had identical half-times for Rat-1 and R7080 cells (tfast = 7 min and tslow = 135 min). However, there was a significant difference between the cell lines in the fractions of DSBs repaired with slow and fast kinetics. In R7080 cells, about twice as many DSBs were repaired with slow kinetics compared to Rat-1 cells (34% compared to 16%). A similar difference was found in the number of residual DSBs (3.6% compared to 2.0%). R7080 cells also showed a reduced capacity to repair chromosome damage as detected by the PCC technique. Concerning cell killing, R7080 cells were clearly more radiosensitive than Rat-1 cells (D0.1 = 6.4 compared to 10.5 Gy), and this increase in sensitivity correlated well with the increase in residual DSBs. The two cell lines, however, did not vary in cell recovery. For sublethal as well as potentially lethal damage, Rat-1 and R7080 cells showed identical recovery ratios. These data demonstrate that the overexpression of human Ku70/Ku80 led to a reduced capacity for DSB repair with an associated increase in cell sensitivity but with no effect on cell recovery.     

Molecular characterization of X-ray-induced mutations at the HPRT locus in plateau-phase Chinese hamster ovary cells

CHO-K1 cells were irradiated in plateau phase to determine the effect of dose, dose fractionation, and delayed replating on the type, location and frequency of mutations induced by 250 kVp X-rays at the hypoxanthine-guanine phosphoribosyl transferase (HPRT) locus. Independent HPRT-deficient cell lines were isolated from each group for Southern blot analysis using a hamster HPRT cDNA probe. When compared with irradiation with 4 Gy and immediate replating, dose fractionation (2 Gy + 24 h + 2 Gy) the entire gene. Since an increase in survival was noted under these conditions, these data suggest that repair of sublethal and potentially lethal damage acts equally on all premutagenic lesions, regardless of type or location. Differences in the mutation spectrum were noted when cells were irradiated at 2 Gy and replated immediately. The location of the deletion breakpoints was determined in 15 mutants showing partial loss of the HPRT locus. In 12 of these cell lines one or both of the breakpoints appeared to be located near the center of the gene, indicating a nonrandom distribution of mutations. These results indicate that damage induced by ionizing radiation results in a nonrandom distribution of genetic damage, suggesting that certain regions of the genome may be acutely sensitive to the mutagenic effects of ionizing radiation.