Coordinate regulation of proteins associated with radiation resistance in cultured insect cells.

Cultured TN-368 lepidopteran insect cells exhibit a pronounced resistance to the lethal effects of a variety of physical agents, including X rays and 254 nm UV light, as well as a large number of chemicals. The resistance to ionizing radiation has previously been associated with an inducible process which is not expressed in unirradiated cells or cells receiving less than some minimal amount of radiation necessary for activating the process. The studies in this paper were initiated in an attempt to identify and characterize the inducible proteins associated with the marked radiation resistance of the TN-368 cells. Cells were exposed to doses of 0, 25, 64 or 350 Gy of 137Cs gamma rays and incubated either for 3 h in medium containing [35S]methionine or for 2 h without labeling. Labeled cells were separated into nuclear and cytoplasmic fractions and proteins were analyzed on two-dimensional polyacrylamide gels. Unlabeled cells were used to isolate total RNA which was translated in vitro in a rabbit reticulocyte lysate system with 35S label. These translation products were also analyzed by two-dimensional electrophoresis. Gamma irradiation of the TN-368 cells resulted in the de novo synthesis of several proteins as well as the complete inhibition of others. The number of such proteins identified was 19. These proteins ranged in size from 18-73 kDa, with a pI distribution of 4.7 to 6.1. In addition to the unique proteins, a large number of other proteins were also either up- or down-regulated. These observations were made in both nuclear and cytoplasmic fractions as well as in the translation products of RNA produced after irradiation. These studies indicate that RNA and protein synthesis in lepidopteran cells are coordinately regulated in response to ionizing radiation and may participate in the pronounced radioresistance of the TN-368 cells.

The effect of tissue expansion on the random flap viability and wound tensile strength of previously irradiated rabbit skin.

Tissue expansion facilitates coverage of cutaneous defects both through the generation of additional skin surface area and by increasing random flap length/width viability factors. The opportunity to apply tissue expansion techniques to head and neck defects within previously irradiated skin fields continues to increase. To study the effect of tissue expansion on the cutaneous perfusion and wound-healing capacity of irradiation-damaged skin, rabbit scalps were subjected to 5 weeks of fractionated radiation followed at 4 months by prolonged tissue expansion. Standardized random flaps were then created and reset within the expanded skin and analyzed in parallel with nonirradiated and nonexpanded control animals. Flap viability as expressed by area and mean maximum length was determined at 10 days postwounding followed by determination of wound-breaking strength. Irradiated tissues demonstrated a significantly reduced flap viability that was significantly increased by expansion. However, tissue expansion-related increases in flap length exceeded those expressed as percent of total area surviving for irradiated animals. Tissue expansion resulted in significant increases in wound tensile strength only in nonirradiated animals. These findings suggest that, compared with controls, several of the benefits of tissue expansion are less appreciable in radiation-damaged skin.

Radiosensitization of human tumor cells with levamisole.

Levamisole in combination with radiation and chemotherapeutic agents is being studied in clinical trials. The mechanism of interaction of levamisole with these modalities is unknown. In order to determine if there is direct interaction between radiation and levamisole, a series of colony-formation assays was performed with the use of two human tumor cell lines. Cells were exposed to 0-10 Gy of radiation, with or without the addition of 0-1000 microM levamisole. Exposure to levamisole alone had no effect on cell survival; however, the combination of continuous exposure to levamisole at concentrations approaching 1000 microM and radiation revealed a potentiation of radiation-induced cell killing.

The effect of tissue expansion on previously irradiated skin.

Opinion remains divided over the advisability of tissue expansion in previously irradiated skin. We examined the properties of, and complications associated with, tissue expansion in previously irradiated rabbit scalps. Irradiation injury was produced using fractionated roentgen rays, with a total dose of 5000 cGy over a 5-week interval. Following a 20-week convalescence interval, expansion was incrementally conducted over 4 weeks. Monitored parameters included cutaneous perfusion as indicated by fiberoptic dermofluorometry, intraluminal pressure, linear surface gain, and area of surface necrosis. The incidence and severity of complications, including surface necrosis, were significantly higher among irradiated animals. Furthermore, the overlying skin of irradiated animals demonstrated a significantly decreased compliance and measurable area gain. Given the inferior expansibility and higher tendency toward complications with contemporary expansion techniques in previously irradiated skin, alternate reconstructive options are preferable in this setting.

Effect of external beam irradiation on neointimal hyperplasia after experimental coronary artery injury.

Human coronary artery restenosis after percutaneous revascularization is a response to mechanical injury. Smooth muscle cell proliferation is a major component of restenosis, resulting in obstructive neointimal hyperplasia. Because ionizing radiation inhibits cellular proliferation, this study tested in a porcine coronary injury model the hypothesis that the hyperplastic response to coronary artery injury would be attenuated by X-irradiation. Deep arterial injury was produced in 37 porcine left anterior descending coronary artery segments with overexpanded, percutaneously delivered tantalum wire coils. Three groups of pigs were irradiated with 300-kV X-rays after coil injury: Group I (n = 10), 400 cGy at 1 day; Group II (n = 10), 400 cGy at 1 day and 400 cGy at 4 days and Group III (n = 9), 800 cGy at 1 day. Eight pigs in the control group underwent identical injury but received no radiation. Treatment efficacy was histologically assessed by measuring neointimal thickness and percent area stenosis. Mean neointimal thickness in all irradiated groups was significantly higher than in the control groups and thickness was proportional to X-ray dose. X-irradiation delivered at these doses and times did not inhibit proliferative neointima. Rather, it accentuated the neointimal response to acute arterial injury and may have potentiated that injury.

Heat resistance and thermotolerance in a radiation-resistant cell line.

Exponentially growing TN-368 lepidopteran insect cells have a normal growth temperature of 28 degrees C. These cells were heated in water baths at various temperatures between 33 and 44 degrees C under conditions of constant or fractionated heating. Determinations of cell survival using colony formation as well as measurements of DNA and protein synthesis were performed to assess relative heat resistance and development of thermotolerance. The results demonstrate a marked heat resistance over previously reported findings from the same laboratory for dipteran Drosophila cells in culture. The degree of heat resistance is remarkable, especially when compared to the heat resistance of mammalian cells, i.e. TN-368 cell survival at 41.5 and 44 degrees C was somewhat similar to mammalian cell survival, even though these temperatures are 13.5 and 16 degrees C above the normal growth temperature for TN-368 cells and 4.5 and 7 degrees C above the growth temperature of mammalian cells. Furthermore, the lepidopteran cells maintain the ability to develop a notable amount of thermotolerance in addition to this heat resistance. Thermotolerance development alone is capable of enhancing survival by an additional 10,000-fold. Thermotolerance could also be detected at the level of protein synthesis as a more rapid recovery following heat treatment. In contrast, DNA synthesis inhibition was prolonged even further in cells receiving a prior heat treatment to induce thermotolerance. In summary, it appears that, in addition to their pronounced radiation resistance, the TN-368 cells are also quite resistant to heat. It remains to be seen whether a single mechanism could be responsible for resistance to these agents which act very differently.

Gamma-ray- and UV-sensitive strains of a radioresistant cell line: isolation and cross-sensitivity to other agents.

Two gamma-ray-sensitive and two ultraviolet (UV)-sensitive variants were isolated from the gamma-ray- and UV-resistant TN-368 lepidopteran insect cell line. The isolation was performed by inducing mutations in the TN-368 cells using ethyl methanesulfonate, growing them for an expression period, irradiating with 137Cs gamma rays or 254-nm UV radiation, allowing cells to incorporate 5-bromodeoxyuridine (BrdU) in the presence of hydroxyurea (DNA repair synthesis), and finally irradiating with 365-nm UV radiation to cause DNA strand breakage at sites of BrdU incorporation with the intent of killing those cells that have undergone DNA repair synthesis and sparing those cells which, for a variety of reasons, did not. The survival of the Cs2 and Cs7 variants exposed to X rays is significantly different from the parent TN-368 line at the P less than 0.0001 level. The survival of the UV10 and UV19 variants exposed to UV radiation is different from the parent at the P less than 0.0001 and P less than 0.003 levels, respectively. In cross-sensitivity testing of the gamma-ray-sensitive variants, only Cs2 is more sensitive to 254-nm UV and only Cs7 is more sensitive to 44 degrees C heating; both are sensitive to PUVA. The UV-sensitive mutants are both sensitive to X irradiation, PUVA, and mitomycin C. However, UV10 is not sensitive to 44 degrees C heating while UV19 is, making UV19 the only variant strain sensitive to all agents examined. Despite the isolation procedure which was intended to select for DNA repair-deficient cells, the results suggest that a more general mechanism is responsible for the sensitivity of the variant cells to the agents tested.

Recovery from exposure to DNA-damaging chemicals in radiation-resistant insect cells.

Radioresistant TN-368 lepidopteran insect cells were examined with respect to their sensitivity to the chemical agents methyl methanesulfonate (MMS), N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), propane sultone (PS), mitomycin C (MMC), and 4-nitroquinoline 1-oxide (4NQO). Based on survival ability, the TN-368 cells were more resistant than most mammalian cells to each of these agents. Concentrations of these agents which reduce survival to about 10% were used to assess recovery ability assayed by colony formation in liquid-holding and split-dose experiments. Liquid-holding experiments were performed by exposing cells in the plateau phase of growth for 1 h to 8 mM MMS, 50 microM MNNG, 9 mM PS, 110 microM MMC, or 175 microM 4NQO, removing the drug and incubating cells in spent medium for 6 h, and plating for colony formation. Split-dose experiments were performed by exposing exponentially growing cells to the above drug concentrations for 1 h, incubating in fresh medium for 6 h, exposing the cells to the agent for an additional hour, and plating. The TN-368 cells were able to significantly recover from MMS, MNNG and PS in both types of experiment. Recovery from 4NQO was observed in liquid-holding experiments and not assessed in split-dose experiments. In all cases where recovery was observed, survival enhancement was approximately 2-fold. Recovery from MMC (a cross-linking agent) exposure was not observed in either type of experiment. In addition, recovery from 8-methoxypsoralen plus UVA light (PUVA), another cross-linking treatment, was not observed. These studies indicate that DNA-DNA and/or DNA-protein crosslinking may be important molecular lesions causing death in the lepidopteran cells and that these cells may have some difficulty in repairing such damage.

pH dependency of cell attachment and growth at both clonal and subculture densities of cultured lepidopteran cells.

TN-368 cells were seeded at 10(6) per flask in TNM-FH medium adjusted to a variety of pH levels which ranged from approximately 5.9 to 6.8. In general, growth was similar from pH 6.2 to nearly 6.7. The medium pH increased with time in culture to a maximum near 7.0 for all pH levels. Similar results for growth and pH increase were also obtained when the cells were plated at densities of 10(4) and 10(5) per flask. Both the fraction of attached cells and the relative intensity of attachment increased with seeding pH. Cells seeded near pH 6.7 or above frequently required vigorous procedures such as trypsinization to detach them. DNA synthesis was measured and found to be similar for cells seeded in medium between pH 6.2 and 6.7. Colony forming efficiency increased from approximately 27% at pH 5.9 to 39% at 6.2, remained in the region of 40% between 6.2 and 6.7 with a peak of 48% at 6.6, and plunged abruptly to a few percent just above 6.7 and was near zero above 6.8. Colony morphology was optimal near pH 6.6.

Eluting solution composition affects DNA double-strand break analysis by filter elution.

The filter elution technique was used to assay for 137Cs-induced DNA double-strand breaks (dsb) in V79 Chinese hamster cells. The elutions were performed using two different sets of lysing and eluting solutions at pH 7.2 and 9.6. The data agree with those of others who have demonstrated differences in elution profiles at pH 7.2 and 9.6. In addition, the data indicate that solution composition has a significant effect on elution.

Enhanced recovery from ionizing radiation damage in a lepidopteran insect cell line.

TN-368 lepidopteran insect cells display a pronounced resistance to the lethal effects of ionizing radiation and exhibit superior DNA repair capabilities. When a TN-368 cell population entering stationary growth phase is irradiated with 137Cs gamma rays and then incubated for several hours before cell dilution and plating for colony formation, the surviving fraction is increased several-fold over cells diluted and plated immediately after irradiation. Similarly, the survival of cells plated immediately following the second of two equivalent doses separated by several hours is greater than the survival of cells plated immediately following a single dose equal to the sum of the split doses. Both processes exhibit similar biphasic repair kinetics and reach maximal levels by 6 h. The phenomena appear initially to be analogous to confluent-holding and split-dose recovery as described for mammalian cells. However, the survival levels obtained for doses of 61-306 Gy after allowing for these recovery processes to occur are quite high and greatly exceed survival levels for all but relatively low doses less than 50 Gy. For example, while the survival of cells irradiated with 150 Gy is near 0.15, the survival of cells receiving 306 Gy in two equivalent split doses is approximately 0.77. Even if damage induced by the first of the split doses was completely repaired, it might be expected that the survival would be near the level of the second dose alone, or near 0.15. Instead the survival is approximately five times greater, suggesting that the first split dose stimulated a repair system not present in unirradiated cells. The situation for confluent-holding recovery is similar to that for split-dose recovery.

DNA double-strand break repair in eukaryotic cell lines having radically different radiosensitivities.

TN-368 lepidopteran insect cells are on the order of 100 times more resistant to the lethal effects of ionizing radiation than cultured mammalian cells. DNA double-strand breaks (DSB) are believed by many to be the critical molecular lesion leading to cell death. We have therefore compared the rejoining of DSB in TN-368 and V79 Chinese hamster cells. Cells were irradiated on ice with 137Cs gamma rays at a dose rate of 2.5 Gy/min, incubated for various periods of time, and assayed for DNA DSB using the method of neutral elution. The kinetics of DSB rejoining following a dose of 90.2 Gy is similar for both cell lines with 50% of the rejoining completed in about 12 min. Approximately 83 and 87% of the DSB are rejoined in the TN-368 and V79 cells, respectively, by 1 h postirradiation. However, no further rejoining occurs in the TN-368 cells through at least 6 h postirradiation, whereas approximately 92% of the DSB are rejoined in the V79 cells by 2 h postirradiation. Other studies (from 22.6 to 226 Gy) demonstrate that the amount of rejoining of DSB varies inversely with dose for both cell lines, but this relationship is not as pronounced for the TN-368 cells. In general, these findings do not support the hypothesis that unrejoined DNA DSB represent the critical molecular lesion responsible for cell death.

Factors to consider in performing survival studies with insect cells.

Insect cell lines are not well-suited to colony formation in liquid medium following low-density cell plating. The present studies demonstrate that the time of addition of fetal bovine serum to the culture medium and the number of gamma-irradiated feeder cells added to each plate are important factors in developing a useful colony formation assay. TN-368 lepidopteran and WR69-DM-1 dipteran cell lines were used for these experiments. Both cell types display increased plating efficiencies if serum is added to the medium one or more days prior to plating as compared to adding serum immediately before plating. Growth curves obtained by seeding cells at higher densities also indicate that cell growth is slightly better if serum is added one or more days before seeding. These findings are especially important for survival and toxicity studies because the results demonstrate that even seemingly minor factors involved in cell survival assays may benefit treated cells to a greater degree than untreated control cells, thus providing an erroneous assessment of cell survival.

Photoreactivation of UV damage in cultured Drosophila cells.

Cell survival and photoreactivation of 254 nm ultraviolet (UV) light damage in a wild type Drosophila cell line was assayed by colony formation in liquid medium. Fo, Fq, and extrapolation number for the exponential portion of survival curves are 21 J/m2, 3.6 J/m2, and 1.5 for non-photoreactivated cells and 110 J/m2, 11.2 J/m2, and 1.3 for those exposed to photoreactivating light. Maximal photoreactivation occurs at the 100 J/m2 region of the curve. At 10 and 50% survival, 75-80% of the UV damage was photoreactivable.

Enhanced survival by photoreactivation and liquid holding following UV damage of TN-368 insect cells.

These studies demonstrate that the TN-368 lepidopteran insect cell line, which is extremely resistant to the lethal effects of ionizing radiation, is also quite resistant to 254-nm ultraviolet light. While resistance to ionizing radiation in TN-368 cells has been associated with superior DNA repair processes, previous findings have indicated no correlation between survival ability and amount of unscheduled DNA synthesis in response to ultraviolet light. The present studies were undertaken to define the TN-368 ultraviolet light survival response, the ability of the cells to repair UV-induced damage by photoreactivation, the capacity of the cells to undergo UV repair during liquid holding in the dark, and the relationship between photoreactivation and liquid-holding recovery. Survival was assayed by colony formation. 254-nm irradiations were performed using germicidal lamps and photoreactivation was accomplished using black lights. Photoreactivable sectors of UV damage at 50 and 10% survival are 0.65 and 0.68, respectively. Survival responses, both with and without photoreactivation, have a small initial shoulder followed by an exponential region, and finally the curves continue to decrease but with decreasing slope. F0, Fq, and extrapolation number for the exponential portion of the curves are 77.5 J/m2, 16.8 J/m2, and 1.7 for non-photoreactivated cells and 234 J/m2, 56.1 J/m2, and 1.7 for those exposed to photoreactivating light. In the primarily exponential survival region, the fluences required to produce equivalent levels of survival in photoreactivated cells range from approximately 10.8 to 23.3 times as great as cells receiving UV light alone. The maximum survival enhancement of cells maintained under liquid-holding conditions over cells plated immediately following 100-400 J/m2 irradiations appears to be about 2-fold and occurs at 3-6 h of holding. Photoreactivation alone has a greater enhancement of survival than when photoreactivation follows liquid holding, but when liquid holding follows photoreactivation, the enhancement surpasses that of photoreactivation alone.

Radiation sensitization by oxygen of in vitro mammalian cells: is .O-2 involved?

Oxygen is a potent sensitizer of cells exposed to ionizing radiation, and, although the exact chemical mechanisms are not fully understood, some evidence suggests that this sensitization may involve the formation of superoxide anion radicals (.O-2) [F. Lavelle, A. M. Michelson, and L. Dimitrijevic, Biochem. Biophys. Res. Commun. 55, 350-357 (1973); A. Petkau and W. S. Chelack, Int. J. Radiat. Biol. 26, 421-426 (1974); L. W. Oberley, A. L. Lindgren, S. A. Baker, and R. H. Stevens, Radiat. Res. 68, 320-328 (1976)] To test this hypothesis, we compared the sensitivity of Chinese hamster V79 cells irradiated in O2/N2 and O2/N2O gas mixtures with and without the addition of other radical scavenging agents. In these tests, although oxygen was present, be blocked the radiation-induced reactions of O2 which produce .O-2. We found that the total amount of biological damage depends simply on the concentration of O2 that is present; the overall sensitivity is not reduced when .O-2 cannot be formed. Thus radiation sensitization by O2--at least of this cell line--does not require the formation of superoxide anion radicals.

Relationship between cell survival and heat-stress protein synthesis in a Drosophila cell line.

Heat-stress protein (hsp) kinetics and clonogenic survival were studied at 33, 37 and 42 degrees C in a continuous Drosophila cell line, WR69-DM-1. Induction and repression of hsp were temperature-dependent and independently modulated. The subsequent cell-survival curves were complex; however, survival generally decreased in a time- and temperature-dependent manner during continuous heating at 33, 37 or 42 degrees C. Constant 33 degrees C heating induced five hsp at 90, 72, 70, 24 and 19 kilodaltons (kDa). A 30 min 33 degrees C heat dose led to thermotolerance after 1, 3 or 6 h incubations at 28 degrees C. The hsp synthesized after this dose were quickly repressed, suggesting the cells were able to respond to this stress. Increasing the challenge temperature to 37 degrees C induced three additional hsp at 34, 22 and 14 kDa, but hsp synthesis did not lead to thermotolerance over the 6 h interval. The number and intensity of hsp synthesized was higher and repression was much slower than at 33 degrees C. Heating at 42 degrees C inhibited all protein synthesis, and thermotolerance was not observed. Direct survival data are critical to understanding the role and function of hsp in Drosophila thermotolerance since the relevance of information on number and kinetics of hsp synthesis and their subsequent localization is dubious without it.