Effect of salt solutions on the radiosensitivity of mammalian cells as a function of the state of adhesion and the water structure.

The radiation isodose survival curve of attached Chinese hamster (V79) cells, subjected to a wide concentration range of salt or sucrose solutions, is characterized by two maxima separated by a minimum. Cells are radioprotected at the maxima (high and low hypertonic salt concentrations) while they are radiosensitized at the minimum (intermediate hypertonic salt concentrations). Both cations and anions can alter the cellular radiosensitivity above and beyond the (osmotic) effect observed for cells treated with sucrose solutions. However, the basic curve shape, except in the case of sulphate salts, remains the same. When these experiments are repeated with single cells in suspension, the isodose survival curve is quite different in that high salt concentrations (greater than 0.9 M) do not protect cells in suspension unlike the case with attached cells. The curve shape is also altered in that the second maximum is absent with many salt solutions. If multicellular spheroids are used for these experiments, the data resemble those for single cell suspensions rather than for attached cells. The radiation survival data for cells in suspension in salt solutions correlate with water proton spin-lattice relaxation time (T1) and, in hypo- and iso-tonic solutions, with cell volume.     

Effect of salt solutions on radiosensitivity of mammalian cells. III. Treatment with hypertonic solutions.

V79 Chinese hamster cells were treated with hypertonic solutions of NaCl or KCl and irradiated rat various times before, during, or after exposure to the solution. In solutions of molarities between 0-2 and 0-5 M, the cellular radiosensitivity increases with the molarity of the bathing solution. At these molarities, the hypertonic solution need not be present during irradiation to sensitize cells. Furthermore, radiosensitivity of cells could be increased by exposing cells for longer times to the hypertonic solution before irradiation. At higher salt concentrations (at 1-5 to 1-8 M), significant radioprotection is observed. Survival curve data showed that this protection was characterized by an increase in DO and a decrease in n, while the survival curves of cells sensitized with 0-465 M NaCl or with lower concentrations exhibited mainly changes in DO. The 1-55 M NaCl solution must be present during radiation to give a protective effect. Prolonged exposure to the salt before irradiation reduced the amount of radioprotection afforded by the salt. The results are discussed in terms of the effects of ions on histones, cellular water structure and the cell-aging cycle.     

Effect of salt solutions on the radiosensitivity of mammalian cells. IV. Treatment with NaCl solutions containing ouabain, NEM, PNAP, cysteamine or DMSO.

The effects of a wide concentration range of NaCl solutions containing either ouabain, ethanol, para-nitroacetophenone (PNAP), N-ethylmaleimide (NEM), cysteamine or dimethyl sulphoxide (DMSO) on cellular radiosensitivity have been examined. Ouabain and NEM treatment increased the radiosensitivity of V79 Chinese hamster cells, but the action of these chemicals did not depend on the concentration of NaCl. PNAP increased cellular radiosensitivity with increasing NaCl concentration reaching a maximum effect at 0.6 to 0.7 M NaCl. The radioprotective properties of cysteamine, DMSO and ethanol were all strongly dependent on the NaCl concentration in a complex but qualitatively similar manner. DMSO (2.0 M) increased radiation survival of cells after a 1380 rad dose by a factor of about 10(4) when present in 0.075 M NaCl and by a factor of 8.7 when present in 1.2 M NaCl.     

The effects of various salt and sucrose solutions on the U.V.L. sensitivity of CHO cells.

The response of cultured CHO cells to U.V.L. irradiation during treatment with anisotonic solutions shows that treatment with hypotonic sucrose, NaCl or KCl solutions causes an increase in the cellular U.V.L. sensitivity, while exposure to hypertonic solutions causes a large decrease in U.V.L. sensitivity. Cells exposed to 1.8 M sucrose, NaCl or KCl solutions and given a U.V.L. dose of 252 erg/mm2 towards the end of the 20 min solution exposure time have survival levels which are respectively 228,26, and 23 times higher than the controls, i.e. cells irradiated in phosphate buffered saline. Cell volume data obtained using a Coulter counter, and nuclear area data of attached cells obtained using an optical microscope with a micrometer reticle, show that cell and nuclear size are related to U.V.L. sensitivity. That is, as cells shrink and the nuclear area decreases, the cells become more U.V.L.-resistant. During hypotonic treatment with 0.1 M NaCl, the cell volume, nuclear area and U.V.L. sensitivity increased in the first 2 to 4 min of exposure time, but at longer exposure times (greater than 3 to 4 min), cell volume, nuclear area and cellular U.V.L. sensitivity decreased. For 0.1 M KCl treatment the cells initially displayed a rapid increase in volume, nuclear area and U.V.L. sensitivity, but at the longer exposure times no decrease in cell and nuclear size were observed, and a slight increase in U.V.L. sensitivity occurred. Changes in U.V.L. sensitivity were related to changes in nuclear size and cell volume; however, calculations showed that during hypertonic treatment there is an ionic effect as well as an osmotic effect. That is, the cellular U.V.L. survival in equal hypertonic concentrations of NaCl or KCl was lower than in the same concentration of sucrose.     

Measurement of total, intracellular and surface bound cations in animal cells grown in culture.

A procedure is described in which animal cells grown in culture on a dish are rapidly rinsed in situ with 0.25 M sucrose solutions for subsequent measurement of total, intracellular and rapidly exchangeab le Na+, K+, Mg2+ and Ca2+ by atomic absorption spectrophotometry. Repeated rinses with CO2-free (pH similar to 7) 0.25 M sucrose solution produced essentially no loss of cellular protein or cations. One 10-second rinse with CO2-saturated (pH 4) 0.25 M sucrose solution removed a rapidly proton exchangeable cellular cation fraction which is interpreted as being externally (membrane) bound. Rinses with physiological electrolyte solutions are shown to produce loss of cellular protein as well as displacement of surface exchangeable cations. Thus, isotonic sucrose solution is more satisfactory than electrolytic media for rinsing cultured cells prior to measurement of cellular cations. The technique employing sucrose rinse media is very rapid and reproducible and permits measurement of total, intracellular or surface bound Na+, K+, Mg2+ and Ca2+ in the same sample.     

Biochemical mechanisms underlying the development of radioresistance by cultured peritoneal exudate macrophages

We investigated changes in radiosensitivity of peritoneal exudate macrophage colony-forming cells (PE-CFC) when exudative peritoneal macrophages were cultured in vitro. The change in the shape of the dose-response curve of PE-CFC to ionizing irradiation was partly dependent on the concentration of oxygen in the gas phase of the incubators. When cells were incubated in an environment containing 20% oxygen, the value of both Dq and D0 for PE-CFC increased. The dose-response curve of PE-CFC cultured for 3 days resembled that of alveolar macrophage colony-forming cells (AL-CFC). The changes in radiosensitivity were accompanied by an increase in the level of three antioxidant enzymes: superoxide dismutase, catalase, and glutathione peroxidase. However, when they were cultured in a 6% oxygen environment, only the value of Dq increased. When alveolar macrophages were incubated in vitro, no significant change in the shape of the dose-response curve of AL-CFC was noted whether they were cultured in gas phase containing either 20 or 6% oxygen. It is concluded that the radiosensitivity of PE-CFC changes when they are cultured in vitro. The increase in D0 appears to be related to the intracellular level of antioxidant enzymes.     

The response of ataxia telangiectasia cells to bleomycin.

The autosomal recessive disorder, ataxia telangiectasia (AT) is characterised by cellular sensitivity to ionizing radiation. The molecular basis of this radiosensitivity is the subject of controversy. We report here that cultured fibroblasts from AT patients are also sensitive to the lethal effects of bleomycin. As with ionizing radiation, no defect has been observed in the overall rejoining of single or double-strand breaks produced by bleomycin. Since, however, only apyrimidinic (and to a lesser extent apurinic) sites and strand breaks are known to be produced by bleomycin, we tentatively suggest that AT cells are unable to rejoin a very small fraction of the total strand breaks. We attribute our inability to detect such unrejoined strand breaks to the relative insensitivity of the sucrose gradient procedures normally used to detect strand breaks.     

Evidence on the mechanism of enhanced sucrose uptake at low cell turgor in leaf discs of Phaseolus coccinius

Plants often tolerate water deficits by lowering the osmotic potential of their cell sap. This may be achieved by accumulation of solutes which results in the maintenance of a positive turgor potential. In this study, the effect of water deficit on sugar uptake was investigated in leaf discs of Phaseolus coccinius L. (cv. Scarlet). Evidence is presented that cell turgor affects the kinetics of sugar transport at the membrane level. Uptake kinetics of sucrose, glucose and 3-O-methyl glucose by tissues equilibrated in solutions of relatively high (200–400 mOsm) osmotic concentration consisted of a sat-urable and a linear component. Low external osmotic concentration i.e., high cellular turgor inhibited the saturating component of sucrose uptake, resulting in a linear uptake profile. However, high cell turgor had no effect on glucose or 3-O-methyl glucose uptake kinetics. The effect of turgor versus osmotic component of water potential was differentiated by comparing responses to non-penetrating (manmtol) or polyethylene glycol, (3350) and penetrating (ethylene glycal) osmotica. Changes in sucrose uptake rates and kinetics were due to changes in cellular turgor and not osmotic potential. Furthermore, at low cellular turgor, a net increase in sucrose uptake occurred as a consequence of enhanced influx rates and not as a result of reduced efflux rates. The data are consistent with previous findings that sugar uptake rates are enhanced under low turgor. We present first evidence indicating that the mechanism by which higher rates of sucrose uptake are maintained underwater deficit conditions is by the activation of the saturable transport system. This mechanism supports previous suggestions that changes in cell turgor are sensed and manifested at the membrane level.     

Role of DNA-PK subunits in radiosensitization by hyperthermia.

Thermal radiosensitization is thought to result from inhibition of repair of radiation-induced DNA damage, DNA double-strand breaks in particular. Since the DNA-dependent protein kinase (DNA-PK) complex plays a major role in the nonhomologous end-joining of DSBs, it has been suggested that inactivation of this complex as a whole or of its individual subunits by heat might be involved in radiosensitization by heat. To test this hypothesis further, the ability of heat to enhance the radiosensitivity of cells proficient or deficient in either Ku80 or the DNA-PK catalytic subunit (DNA-PKcs) was investigated. In cells of two Ku80-deficient and two DNA-PKcs-deficient and double-strand break-deficient cell lines, the extent of radiosensitization by heat was not reduced compared to that in both their isogenic gene-complemented counterparts as well as to that in their parental cells. Thus radiosensitization by hyperthermia can be obtained irrespective of the Ku80 or DNA-PKcs status in cells. Therefore, Ku80 or DNA-PKcs and hence nonhomologous DSB end-joining do not play a crucial role in the enhancement of cellular radiosensitivity by hyperthermia.     

Rapid-mixing studies of radiosensitivity with thiol-depleted mammalian cells

A moderate reduction in the non-protein thiol content of V79 379A Chinese hamster cells, obtained by pretreatment with buthionine sulphoximine (BSO), diethyl maleate (DEM) or N-ethyl maleimide (NEM), increase both the absolute radiosensitivity of the cells in hypoxia and the radiosensitizing effect of adding oxygen 7 ms after irradiation. Combined pretreatment of cells with BSO and NEM removes most of the non-protein thiol and some of the protein thiol; such treatment further increases the radiosensitivity of hypoxic cells but there is no further effect of adding oxygen 7 ms after irradiation. Addition of 2-mercaptoethanol to cells 7 ms after irradiation gives protection factors that increase with increasing severity of thiol depletion. Substantial radioprotection can still be observed when 2-mercaptoethanol is added 70 ms after irradiation of cells pretreated with BSO and NEM; there is no effect of adding 2-mercaptoethanol to such cells 50s after irradiation. These observations support the repair-fixation model of radiation damage and suggest that, in addition to the established role of non-protein thiol in chemical repair of radiation damage, other endogenous reducing agents such as protein thiol may be important in determining cellular radiosensitivity. A relatively long-lived thiol-modifiable component of radiation damage has been observed within hypoxic thiol-depleted cells.     

Hemolysis of human red blood cells by freezing and thawing in solutions containing sucrose: relationship with posthypertonic hemolysis and solute movements

Human red blood cells were frozen at temperatures down to ?9 °C in solutions containing sucrose, and the hemolysis on thawing was measured. This was compared with the hemolysis caused by exposing the cells to high concentrations of sucrose and then resuspending them in more dilute solutions at 4 °C. The effects of the hypertonic solutions of sucrose on potassium, sodium, and sucrose movements were also investigated. It was found that sucrose does not prevent damage to the cells by very hypertonic solutions (whether during freezing and thawing or at 4 °C) but it does reduce hemolysis of cells previously exposed to these solutions if present in the resuspension (or thawing) solution. Evidence is presented that the damaging effects of the hypertonic solutions of sucrose occurring during freezing are associated with changes in cell membrane permeability but that posthypertonic hemolysis is not primarily associated with a “loading” of the cells with extracellular solutes in the hypertonic phase. It is concluded that sucrose may reduce hemolysis of red blood cells by slow freezing and thawing by reducing colloid osmotic swelling of cells with abnormally permeable membranes.     

Effect of X rays on protein synthesis and RNA synthesis in adenovirus-infected cells.

Ionizing radiation exerts a deteriorating effect on the rate of protein and RNA synthesis in HeLa cells. This effect is higher in cells infected with adenovirus, thus pointing to a higher radiosensitivity of viral syntheses compared with the cellular ones.     

Radio- and thermosensitivity of E. coli K1060 after thiol depletion by diethylmaleate

Summary The Escherichia coli auxotroph K1060 has been grown in a medium supplemented with either oleic acid (18 : 1) or linolenic acid (18 : 3) and its radiosensitivity and thermosensitivity established using bacterial cell survival as the assay system. No difference in radiosensitivity was observed when oleic and linolenic grown cells were exposed to-radiation at room temperature. When heated at 49° C linolenic grown cells were more sensitive than oleic grown cells.To investigate whether soluble -SH compounds, e.g., glutathione (GSH), were critical in protecting cells against radiation or heat, studies were performed using cells depleted of -SH by incubation with diethylmaleate (DEM). After reduction of water-soluble non-protein thiol compounds to 25% (10 mM DEM treatment) of control value, no major changes in radiosensitivity under oxic conditions were found. Radioresistance increased slightly when irradiation was performed under hypoxic conditions. Thermoresistance was clearly stimulated after DEM treatments between 1 and 10 mM DEM.The main conclusion of these experiments is that lowering the cellular level of reduced glutathione may not generally be correlated with a higher radio- and thermosensitivity.     

THE EFFECT OF X-RAY INDUCED SYNCHRONY ON TWO-DOSE CELL SURVIVAL EXPERIMENTS

Calculations were made based on experimental data of the variation in radiosensitivity and in cell cycle delay with age in Chinese hamster cells (Sinclair, 1967, 1968). The computed syntheses included: (a) single-dose survival curves; (b) splitdose recovery curves, the pattern of survival; and (c) two-dose survival curves, the shape of the second survival curve. It is clear that, after an initial dose, changes occur in the subsequent dose-response curve which depend upon size of dose and time after irradiation. Following rapid and apparently complete repair of sublethal injury, these changes can be attributed to progression of a partially synchronized population through phases of varying radiosensitivity. These changes may be small in some systems, but important in others. The concept of equal dose-increments after each of several dose fractions is an over-simplification and must be used with care.     

Dependence of the radiosensitivity of yeast cells on the LET of radiations. Experiments on haploid cells

The previously developed model was used to study the dependence of radiosensitivity (D0(-1) of Saccharomyces cerevisiae (the wild type and radiosensitive mutant) on linear energy transfer (LET) of ionizing radiation. D0(-1) (L) of haploid yeasts was shown to be associated, to a certain extent, with the capacity of radiation damages repair. As to the wild-type cells, the above function was represented by a curve showing a maximum, while a descending curve was characteristic of the radiosensitive mutant cells deficient in radiation damages repair. The influence of the repair processes on cell radiosensitivity decreased with increasing LET.     

The effect of transfection with the oncogenes H-ras and c-myc on the radiosensitivity of a mink epithelial cell line.

We have investigated the effect of transfection with the oncogenes c-myc and H-ras on cellular radiosensitivity. We obtained a mink lung epithelial line, Mv1Lu (ATCC CCL-64), and two sublines which had been transformed by transfection with c-myc and mutated (T24) H-ras 1. The cell survival parameters do not differ significantly between the three lines. These parameters were, for the parent line: D0 = 1.95 Gy, n = 2.0; for the c-myc transfected line: D0 = 2.10 Gy, n = 2.33; and for the H-ras transfected line: D0 = 2.40 Gy, n = 1.77. Although the terminal slope of the survival curve of the cells of the parent line is slightly steeper than that for the cells of either of the transfected lines, the differences are not significant. Nor is there any difference between the cell lines at the clinically relevant dose of 2 Gy. We conclude that neither activated H-ras nor c-myc oncogenes alter the radiosensitivity of the Mv1Lu line.     

THE OSMOTIC EFFECTS OF ELECTRON MICROSCOPE FIXATIVES

The reflecting cells on the scales of sprat and herring contain ordered arrays of guanine crystals. The spacing of the crystals within these cells determines the wave bands of the light which they reflect, hence volume changes in the reflecting cells can be observed as color changes directly. This property of the scales is used to show that (a) fixation with osmium tetroxide solutions destroys osmotic activity; (b) fixation with aldehyde solutions does not destroy osmotic activity and does not cause volume changes if the aldehydes are made up in salt or sucrose solutions whose osmolarities, discounting the aldehyde, are about 60% of those to which the cells are in equilibrium in life, and (c) after aldehyde fixation the cells are osmotically active but come to a given volume in salt and sucrose solutions of concentrations only 60% of those which give their volume before fixation. Various possible mechanisms underlying the change of osmotic equilibrium caused by aldehyde fixation are discussed.     

Induction and rejoining of DNA double-strand breaks in human cervix carcinoma cell lines of differing radiosensitivity

Five recently established cell lines of human carcinoma of the cervix of varying radiosensitivity have been used to determine whether the induction or rejoining of DNA double-strand breaks (dsb) shows any correlation with radiosensitivity or radiation recovery capacity. Double-strand DNA breaks have been measured using neutral filter elution at pH 9.6. The number of breaks induced immediately after irradiation with doses of 10 to 40 Gy 60Co gamma rays appeared to show some correlation with radiosensitivity particularly after 10 Gy; the two more radiosensitive lines incurred more breaks than the more radioresistant lines. In addition, the shape of the induction curve with dose was linear for the two sensitive lines but curvilinear for the resistant lines. Despite the dose scales being different, this mirrored their respective cell survival curve shapes. After 30 or 50 Gy irradiation, rejoining of breaks appeared to be rapid and almost complete within 60 min at 37 degrees C for the three resistant lines. However, for the sensitive lines, one line (HX160c) in particular exhibited a reduced rate of dsb rejoining. In addition, a residual level of dsb was present in this line even after allowing rejoining for 3 h. While induction and rejoining of DNA dsb therefore appears to be a factor in determining radiosensitivity, at doses relevant to cellular survival (up to 10 Gy), the greater induction of DNA dsb in radiosensitive lines may play a significant role in determining the cellular response to ionizing radiation.     

Estimation of macromolecule concentrations and excluded volume effects for the cytoplasm of Escherichia coli.

The very high concentration of macromolecules within cells can potentially have an overwhelming effect on the thermodynamic activity of cellular components because of excluded volume effects. To estimate the magnitudes of such effects, we have made an experimental study of the cytoplasm of Escherichia coli. Parameters from cells and cell extracts are used to calculate approximate activity coefficients for cytoplasmic conditions. These calculations require a representation of the sizes, concentrations and effective specific volumes of the macromolecules in the extracts. Macromolecule size representations are obtained either by applying a two-phase distribution assay to define a related homogeneous solution or by using the molecular mass distribution of macromolecules from gel filtration. Macromolecule concentrations in cytoplasm are obtained from analyses of extracts by applying a correction for the dilution that occurs during extraction. That factor is determined from experiments based upon the known impermeability of the cytoplasmic volume to sucrose in intact E. coli. Macromolecule concentrations in the cytoplasm of E. coli in either exponential or stationary growth phase are estimated to be approximately 0.3 to 0.4 g/ml. Macromolecule specific volumes are inferred from the composition of close-packed precipitates induced by polyethylene glycol. Several well-characterized proteins which bind to DNA (lac repressor, RNA polymerase) are extremely sensitive to changes in salt concentration in studies in vitro, but are insensitive in studies in vivo. Application of the activity coefficients from the present work indicates that at least part of this discrepancy arises from the difference in excluded volumes in these studies. Applications of the activity coefficients to solubility or to association reactions are also discussed, as are changes associated with cell growth phase and osmotic or other effects. The use of solutions of purified macromolecules that emulate the crowding conditions inferred for cytoplasm is discussed.     

Independence of the radiobiological oxygen constant, K, and the respiration rate of mammalian cells.

The radiosensitivity, and the radiobiological oxygen-constant K for mouse Ehrlich ascites cells depend on the pre-irradiation growth conditions. Measurements of the oxygen-consumption rate of cells grown by different methods have been made to ascertain whether the differences in radiobiological properties could be associated with different rates of respiration. Inhibition of respiration by sodium amytal had no significant effect on either the radiosensitivity or the estimate of K.