Effect of thermotolerance on thermal radiosensitization in hepatoma cells

The interaction between hyperthermia and X irradiation was determined in cultured Reuber H35 hepatoma cells with different states of thermosensitivity. Incubation at 41 degrees C followed by 4-Gy X rays resulted after 2 hr in a stabilization of cell survival for heat or plus X rays, with a maximum synergism factor of 1.6. Thermotolerance did not develop during incubation at 41.7 or 42.5 degrees C. When heat treatment of cells was followed by irradiation, the synergism factor for thermal radiosensitization increased with both the amount of thermal cell killing and the amount of X-ray cell killing; the influence of thermal exposure on the synergism factor was greater than that of the X-ray dose. Cells were made thermotolerant either by incubation at 42.5 degrees C for 30 or 60 min followed by an interval at 37 degrees C, or by continuous incubation at 41 degrees C. In both cases thermotolerance was measured by incubation at 42.5 degrees C. No difference was observed between the maximum thermotolerance achieved with both methods. When cells were irradiated in addition to the second heat treatment, thermal radiosensitization was strongly reduced concomitant with the decreased sensitivity to killing by heat.     

Exposure to pretreatment hypothermia as a determinant of heat killing

When Chinese hamster ovary (CHO) cells were exposed to 22 degrees C for 2 hr prior to 42.4 degrees C hyperthermia, neither the shoulder region of the survival curve nor the characteristic development of thermotolerance after 3-4 hr of heating were observed. Absolute cell survival after 4 hr at 42.4 degrees C was decreased by a factor of between 10 and 100 (depending on the rate of heating of nonprecooled controls). Conditioning at 30 degrees C for 2 hr, 26 degrees C for 2 hr, or 22 degrees C for 20 min followed by heating to 42.4 degrees C over 30 min did not result in sensitization. Prolonged (16 hr) conditioning at 30 degrees C, however, increased the cytotoxicity of immediate exposure to 41.4 or 45 degrees C with maximum sensitization to 45 degrees C occurring after 6 hr at 30 degrees C. Both 3- and 18-hr pretreatments at 30 degrees C similarly increased the cytotoxicity of 45-41.5 degrees C step-down heating (D0 = 28 min in precooled versus 40 min in nonprecooled cells).     

Effects of m-aminobenzamide on the response of Chinese hamster cells to hyperthermia and/or radiation

The modifying effects of m-aminobenzamide (m-ABA), an inhibitor of poly(ADP-ribose) synthesis, on 42 degrees C hyperthermia- and/or radiation-induced cell killing were examined in Chinese hamster V-79 cells. When cells were exposed to 42 degrees C hyperthermia in combination with m-ABA (10 mM), cell survival decreased compared with that for 42 degrees C hyperthermia alone. Thermosensitizing effects of m-ABA changed with treatments in a decreasing order of during and after heating greater than during heating greater than after heating. Treatments with m-ABA during and/or after X irradiation enhanced radiation-induced cell killing. When cells were exposed to combined treatment with X irradiation, 42 degrees C hyperthermia (60 min), and m-ABA (24 hr), cell survival decreased markedly compared with that for X irradiation alone. However, with both X----42 degrees C and X----42 degrees C----m-ABA, the enhancement ratios (ER), designated as D0 ratio, were similar. These results suggest that the mechanisms of radiosensitization by m-ABA may be similar to those of 42 degrees C hyperthermia.     

The effect of hyperthermia on radiation-induced carcinogenesis

Ten groups of mice were exposed to either a single (30 Gy) or multiple (six fractions of 6 Gy) X-ray doses to the leg. Eight of these groups had the irradiated leg made hyperthermic for 45 min immediately following the X irradiation to temperatures of 37 to 43 degrees C. Eight control groups had their legs made hyperthermic with a single exposure or six exposures to heat as the only treatment. In mice exposed to radiation only, the postexposure subcutaneous temperature was 36.0 +/- 1.1 degrees C. Hyperthermia alone was not carcinogenic. At none of the hyperthermic temperatures was the incidence of tumors in the treated leg different from that induced by X rays alone. The incidence of tumors developing in anatomic sites other than the treated leg was decreased in mice where the leg was exposed to hyperthermia compared to mice where the leg was irradiated. A systemic effect of local hyperthermia is suggested to account for this observation. In mice given single X-ray doses and hyperthermia, temperatures of 37, 39, or 41 degrees C did not influence radiation damage as measured by the acute skin reactions. A hyperthermic temperature of 43 degrees C potentiated the acute radiation reaction (thermal enhancement factor 1.1). In the group subjected to hyperthermic temperatures of 37 or 39 degrees C and X rays given in six fractions, the skin reaction was no different from that of the group receiving X rays alone. Hyperthermic temperatures of 41 and 43 degrees C resulted in a thermal enhancement of 1.16 and 1.36 for the acute skin reactions. From Day 50 to Day 600 after treatment, the skin reactions showed regular fluctuations with a 150-day periodicity. Following a fractionated schedule of combined hyperthermia and X rays, late damage to the leg was less than that following X irradiation alone. Mice subjected to X rays and hyperthermic temperatures of 41 and 43 degrees C had a lower median survival time than the mice treated with hyperthermia alone. This effect was not associated with tumor incidence.     

Radiosensitivity and thermosensitization of thermotolerant Chinese hamster cells and RIF-1 tumors

CHO cells subline HA-1 were made thermotolerant by a priming heat treatment (43 degrees C, 30 min). Later, 4, 16, or 24 hr, they were either irradiated or heated (43 degrees C, 30 min) and irradiated. Thermotolerance had no effect on the radiation sensitivity of the cells as measured by the D0 value of the clonogenic survival curve. However, the N value of the curve (width of shoulder) showed a significant increase at 24 hr, indicating an increased capacity to accumulate sublethal damage. This indicates that the fractionation schedule 43 degrees C, 30 min + 37 degrees C, 24 hr + 43 degrees C, 30 min + X ray required approximately 100 rad more radiation than 43 degrees C, 30 min + X ray to reduce survival to the same level. The same priming treatment was given to RIF-1 tumors growing in C3H mice. Later, 24 hr, when the tumors were either irradiated or heated (43 degrees C, 30 min) and irradiated, it was found that thermotolerance had no effect on the radiosensitivity of the cells as measured by in vitro assay. However, thermal radiosensitization was not apparent 24 hr after the priming treatment.     

The cell cycle dependence of thermotolerance. II. CHO cells heated at 45.0 degrees C

This report extends our investigations of the cell cycle dependence of the expression of thermotolerance to include tolerance expressed by Chinese hamster ovary (CHO) cells exposed to 45.0 degrees C hyperthermia. We examined the response of asynchronous cells following exposure at 45.0 degrees C. A maximum in thermotolerance under these conditions was reached approximately 12 hr after a 15-min exposure to 45.0 degrees C hyperthermia and progressively decreased thereafter. Cells were delayed in S and G2 phase for 24 hr, after which time cell growth resumed. We then characterized the response of CHO cell populations synchronized in G1 or early or late S phase. We observed that the expression of tolerance depended on the position of cells in the cell cycle and was modulated by changes in the sensitivity of cells as they progressed through the cell cycle subsequent to the tolerance induction dose. We measured the variation in the sensitivity of these cells to 45.0 degrees C hyperthermia throughout the cell cycle and found substantial changes as cells progressed through S phase. Cells in early S phase were the most sensitive to heat at this temperature, and as these cells progressed through S phase, they became progressively more resistant. In addition, G1 cells were delayed for approximately 15 to 18 hr by a 15-min, 45.0 degrees C heat pulse, whereas S-phase cells were delayed to a lesser extent. The data presented in this report suggest that the induction of thermotolerance is relatively non-cell-cycle specific, but the magnitude of expression of tolerance depends on the position of cells in the cell cycle at the time of the subsequent challenge heat dose.     

Correlation between cellular survival and potassium loss in mouse fibroblasts after hyperthermia alone and after a combined treatment with X rays

Mouse fibroblast LM cells have been heated at 44 degrees C for different periods. Potassium content of the cells was measured at certain intervals during the postheating period at 37 degrees C for up to 24 hr. The level of K+ decreased gradually in time starting within some hours after the heat treatment. The rate of K+ loss as well as the ultimate level reached was heat-dose dependent. When the potassium content of the cell population was determined 16 hr after the heat treatment, a correlation was observed between the concentration of potassium and the level of cell survival. When X irradiation was applied immediately after hyperthermia, radiosensitization on the level of cell survival was obtained as expected, the extent being dependent on the severity of heat treatments. No added K+ loss was observed, however, when hyperthermia was combined with radiation. It is suggested that plasma membrane related functions are disturbed by the heat treatment. This points to membranes as possible candidates for primary targets in the case of cell inactivation by heat alone, and not with respect to the radiosensitization by hyperthermia.     

Covalent DNA-protein crosslinking occurs after hyperthermia and radiation

Covalent DNA-protein crosslinks occur in exponentially growing mouse leukemia cells (L1210) after exposure to ionizing radiation. The amount of DNA-protein crosslinks as measured by a filter binding assay is dose dependent upon X irradiation. Although hyperthermia and radiation in combination are synergistic with respect to cell lethality, the combination does not result in an increase of DNA-protein crosslinks when assayed immediately following treatments. Hyperthermia (43 degrees C/15 min) given prior to radiation does not alter the radiation dose dependency of the amount of initial crosslinking. In addition, the amount of DNA-protein crosslinking produced by heat plus radiation is independent of the length of heating the cells at 43 degrees C. The DNA-protein crosslinks produced by 50-Gy X ray alone are removed after 2 hr at 37 degrees C. However, if hyperthermia (43 degrees C/15 min) is given prior to 100-Gy X ray, the removal of DNA-protein crosslinks is delayed until 4.0 hr after radiation. Phospho-serine and phospho-threonine bonds are not produced with either radiation or the combination of hyperthermia plus radiation as judged by the resistance of the bonds to guanidine hydrochloride. However, hyperthermia plus radiation causes an increase in phosphate to nitrogen type bonding. These results show that radiation alone causes covalent DNA-protein crosslinks. Hyperthermia in combination with radiation does not increase the total amount of the crosslinks but delays the removal of the crosslinks and alters the distribution of the types of chemical bonding. These data suggest that the synergistic action on hyperthermia with radiation is more related to the rate of removal and the type of chemical bonding involved in the covalent DNA-protein crosslinks rather than the amount of DNA-protein crosslinks.     

Influence of hyperthermia on gamma-ray-induced mutation in V79 cells

Asynchronously growing V79 cells were assayed for mutation induction following exposure to hyperthermia either immediately before or after being irradiated with 60Co gamma rays. Hyperthermia exposures consisted of either 43.5 degrees C for 30 min or 45 degrees C for 10 min. Each of these heat treatments resulted in a survival level of 42%. For all sequences of combined treatment with hyperthermia and radiation, cell killing by gamma rays was enhanced. Mutation induction by gamma rays was enhanced when heat preceded gamma irradiation, but no increase was observed when heat was given after gamma exposures. Treatment at 45 degrees C for 10 min gave a higher yield in mutants at all gamma doses studied compared to treatment at 43.5 degrees C for 30 min. When heat-treated cells were incubated for different periods before being exposed to gamma rays, thermal enhancement of radiation killing was lost after 24 h. In contrast, only 5-6 h incubation was needed for loss of mutation induction enhancement.     

Thermosensitization by methylglyoxal bis(guanylhydrazone) in Chinese hamster cells

The modification of methylglyoxal bis(guanylhydrazone) (MGBG) by 42 degrees C hyperthermia-and/or radiation-induced cell killing was examined in Chinese hamster V-79 cells. At concentrations of more than 10 microM, cell survival decreased exponentially with increased MGBG exposure times. Cell lethality of MGBG (10 microM) was not specific for cell-cycle phases tested from G1/S through G2. When cells were treated with MGBG (10 microM) for 6 hr and then exposed to 42 degrees C hyperthermia with or without a 24-hr interval, cell survival decreased markedly compared with that for 42 degrees C alone. Cells became thermosensitive after MGBG treatment. Cells exposed to MGBG (10 microM) for 6 hr before or after X irradiation were slightly radiosensitive. When X irradiation was combined with MGBG and 42 degrees C hyperthermia, cells became more radiosensitive. From these results, it is suggested that MGBG may change the intracellular state to sensitize cells to the cytotoxic action(s) of hyperthermia.     

Relative biological effectiveness of the alpha-particle emitter (211)At for double-strand break induction in human fibroblasts

The purpose of this study was to quantify and to determine the distribution of DNA double-strand breaks (DSBs) in human cells irradiated in vitro and to evaluate the relative biological effectiveness (RBE) of the alpha-particle emitter (211)At for DSB induction. The influence of the irradiation temperature on the induction of DSBs was also investigated. Human fibroblasts were irradiated as intact cells with alpha particles from (211)At, (60)Co gamma rays and X rays. The numbers and distributions of DSBs were determined by pulsed-field gel electrophoresis with fragment analysis for separation of DNA fragments in sizes 10 kbp-5.7 Mbp. A non-random distribution was found for DSB induction after irradiation with alpha particles from (211)At, while irradiation with low-LET radiation led to more random distributions. The RBEs for DSB induction were 2.1 and 3.1 for (60)Co gamma rays and X rays as the reference radiation, respectively. In the experiments studying temperature effects, nuclear monolayers were irradiated with (211)At alpha particles or (60)Co gamma rays at 2 degrees C or 37 degrees C and intact cells were irradiated with (211)At alpha particles at the same temperatures. The dose-modifying factor (DMF(temp)) for irradiation of nuclear monolayers at 37 degrees C compared with 2 degrees C was 1.7 for (211)At alpha particles and 1.6 for (60)Co gamma rays. No temperature effect was observed for intact cells irradiated with (211)At. In conclusion, irradiation with alpha particles from (211)At induced two to three times more DSB than gamma rays and X rays.     

Temperature-dependent induction of thermotolerance by ethanol

Ethanol (1 M) cytotoxicity in asynchronous Chinese hamster ovary cells was strongly temperature dependent, yielding families of cell survival curves between 34 and 39 degrees C that were similar to those obtained at hyperthermic temperatures in medium without ethanol. Below 36 degrees C, survival curves were biphasic, indicating the development of thermotolerance during ethanol exposures. At room temperature (22 degrees C) ethanol was completely nontoxic with incubation periods up to 6 h. A comparison of survival curves with and without ethanol showed that the major effect of ethanol was an effective temperature shift of circa 6.5 degrees C, i.e., the cell survival curve at 37 degrees C in 1 M ethanol was equivalent to that at 43.6 degrees C in medium without ethanol. In addition to the effective temperature shift, ethanol also resulted in sensitization to "heat" with a temperature dependence that was similar to the stepdown heating effect. When thermotolerance was induced with acute ethanol exposures (25 min, 37 degrees C or 60 min, 35.5 degrees C), the kinetics and the magnitude of tolerance were similar to those after isotoxic conditioning treatments with heat alone (10 min, 45 degrees C). In contrast, equimolar ethanol at 22 degrees C did not induce thermotolerance. These data provide a rationale for conflicting results in the literature regarding thermotolerance induction by ethanol. Both heat sensitization and the induction of thermotolerance are interpreted as the effect of ethanol on the solution properties of intracellular water. These solvent alterations reduce the temperature necessary to elicit cytotoxicity and the development of thermotolerance.     

Thermotolerance induced by heat, sodium arsenite, or puromycin: its inhibition and differences between 43 degrees C and 45 degrees C

When CHO cells were treated either for 10 min at 45-45.5 degrees C or for 1 hr with 100 microM sodium arsenite (ARS) or for 2 hr with 20 micrograms/ml puromycin (PUR-20), they became thermotolerant to a heat treatment at 45-45.5 degrees C administered 4-14 hr later, with thermotolerance ratios at 10(-3) isosurvival of 4-6, 2-3.2, and 1.7, respectively. These treatments caused an increase in synthesis of HSP families (70, 87, and 110 kDa) relative to total protein synthesis. However, for a given amount of thermotolerance, the ARS and PUR-20 treatments induced 4 times more synthesis than the heat treatment. This decreased effectiveness of the ARS treatment may occur because ARS has been reported to stimulate minimal redistribution of HSP-70 to the nucleus and nucleolus. Inhibiting protein synthesis with cycloheximide (CHM, 10 micrograms/ml) or PUR (100 micrograms/ml) after the initial treatments greatly inhibited thermotolerance to 45-45.5 degrees C in all cases. However, for a challenge at 43 degrees C, thermotolerance was inhibited only for the ARS and PUR-20 treatments. CHM did not suppress heat-induced thermotolerance to 43 degrees C, which was the same as heat protection observed when CHM was added before and during heating at 43 degrees C without the initial heat treatment. These differences between the initial treatments and between 43 and 45 degrees C may possibly be explained by reports that show that heat causes more redistribution of HSP-70 to the nucleus and nucleolus than ARS and that redistribution of HSP-70 can occur during heating at 42 degrees C with or without the presence of CHM. Heating cells at 43 degrees C for 5 hr after thermotolerance had developed induced additional thermotolerance, as measured with a challenge at 45 degrees C immediately after heating at 43 degrees C. Compared to the nonthermotolerant cells, thermotolerance ratios were 10 for the ARS treatment and 8.5 for the initial heat treatment. Adding CHM (10 micrograms/ml) or PUR (100 micrograms/ml) to inhibit protein synthesis during heating at 43 degrees C did not greatly reduce this additional thermotolerance. If, however, protein synthesis was inhibited between the initial heat treatment and heating at 43 degrees C, protein synthesis was required during 43 degrees C for the development of additional thermotolerance to 45 degrees C.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differences in thermotolerance induced by heat or sodium arsenite: cell killing and inhibition of protein synthesis

Chinese hamster ovary (CHO) cells became thermotolerant after treatment with either heat for 10 min at 45.5 degrees C or incubation in 100 microM sodium arsenite for 1 h at 37 degrees C. Thermotolerance was tested using heat treatment at 45 degrees C or 43 degrees C administered 6-12 h after the inducing agent. At 45 degrees C thermotolerance ratios at 10(-2) isosurvival levels were 4.2 and 3.8 for heat and sodium arsenite, respectively. Recovery from heat damage as measured by resumption of protein synthesis was more rapid in heat-induced thermotolerant cells than in either sodium arsenite-induced thermotolerant cells or nonthermotolerant cells. Differences in inhibition of protein synthesis between heat-induced thermotolerant cells and sodium arsenite-induced thermotolerant cells were also evident after test heating at 43 degrees C for 5 h. At this temperature heat-induced thermotolerant cells were protected immediately from inhibition of protein synthesis, whereas sodium arsenite-induced thermotolerant cells, while initially suppressed, gradually recovered within 24 h. Furthermore, adding cycloheximide during the thermotolerance development period greatly inhibited sodium arsenite-induced thermotolerance (SF less than 10(-6] but not heat-induced thermotolerance (SF = 1.7 X 10(-1] when tested with 43 degrees C for 5 h. Our results suggest that both the development of thermotolerance and the thermotolerant state for the two agents, while similar in terms of survival, differed significantly for several parameters associated with protein synthesis.     

Hypothermia: teratogenic and protective effects on the development of mouse embryos in vitro

Hypothermia often occurs in association with clinical conditions involving severe hypoglycemia, but its effect on embryonic development has not been well evaluated. Thus, the whole embryo culture method was used to expose day 9 (neurulating) and day 10 (early limb bud stage) mouse embryos to physiologic levels of hypothermia (35 degrees C and 32 degrees C) for 4 and 24 hr. Embryos were evaluated after 24 hours for growth and malformations and compared with controls grown at 37 degrees C. Lactate production was measured in embryos cultured for 4 hr at 32 degrees C and compared with those cultured at 37 degrees C. A 4-hr exposure to hypothermia produced little effect morphologically but reduced the rate of lactate production at both embryonic stages. A 24-hr exposure to hypothermia at 35 degrees C or 32 degrees C produced growth retardation and dysmorphogenesis in embryos undergoing neurulation. Early limb bud stage embryos were less sensitive to this treatment, with growth retardation produced only at the lower temperature. Since hypothermia is commonly associated with severe hypoglycemia in cases of diabetic insulin overdose, day 9 (neurulating) mouse embryos were exposed concurrently to short periods of hypothermia and hypoglycemia and compared with embryos cultured in hypoglycemic medium at normal temperature. The results demonstrate that hypothermia partially protects embryos against the dysmorphogenic effects of hypoglycemia. A balance of metabolic rate and available substrate is discussed as a possible mechanism for this protective effect.     

Hyperthermic enhancement of antibody-complement cytotoxicity against normal mouse B lymphocytes and its relation to capping

Normal mouse B lymphocytes were exposed to water-bath hyperthermia in vitro and examined for susceptibility to antibody-complement (Ab-C) cytotoxicity. Enhancement of Ab-C cytotoxicity was observed during heat treatment at 42 or 43 degrees C. Sensitivity to Ab-C cytotoxicity returned to normal levels by 2-3 hr post exposure to 42 degrees C. No such recovery was observed when cells were preheated at 43 degrees C for 40 min. The mechanism responsible for heat-induced enhancement of Ab-C cytotoxicity may be related to the way heat affects the redistribution of membrane-bound antigen-antibody (Ag-Ab) complexes. To investigate this possibility, cells were preheated at 37, 42, or 43 degrees C. The Ab-C assay was then performed at 37 degrees C immediately or 2.5 hr after hyperthermia. The distribution of Ag-Ab complexes was evaluated by immunofluorescence. A direct correlation was found between the hyperthermic enhancement of Ab-C cytotoxicity and the hyperthermic inhibition of capping, a process where membrane-bound Ag-Ab complexes coalesce into a polar cap on the cell surface. Sensitivity to Ab-C cytotoxicity returned to normal levels when cells restored the ability to cap Ag-Ab complexes following 42 degrees C hyperthermia. Cells heated at 43 degrees C were still sensitive to Ab-C cytotoxicity and did not recover the capping ability even 2.5 hr after heat treatment.     

Inhibition of heat shock protein synthesis and protein glycosylation by stepdown heating

Mammalian cells exhibit increased sensitivity to hyperthermic temperatures of 38-43 degrees C after an acute high-temperature heat shock; this phenomenon is known as the stepdown heating (SDH) effect. We characterized the SDH effect on (1) the synthesis of major heat shock proteins, HSP110, 90, 72/70, 60 (35S-amino acids label), (2) on heat-induced protein glycosylation (3H-D-mannose label), and (3) on thermotolerance expression, using cell survival as an endpoint. Partitioning of label between soluble and insoluble cell fractions was separately examined. Synthesis of high molecular weight HSPs (HSP110, 90, and 72/70) was increased both by acute (10 min, 45 degrees C) and chronic (1-6 h, 41.5 degrees C) hyperthermia, primarily in the soluble cytosol fraction. SDH (10 min, 45 degrees C + 1 to 6 h, 41.5 degrees C) completely inhibited labeling of HSP110, partially inhibited HSP90 labeling, and had virtually no effect on HSP72/70 synthesis, when compared with chronic hyperthermia alone. At the cell survival level, SDH increased sevenfold the rate of cell killing at 41.5 degrees C, but reduced the expression of thermotolerance by only a factor of two. This suggests that SDH sensitization did not result from changes in HSP72/70 synthesis, nor solely from inhibition of thermotolerance. 35S-labeled HSP60 and HSP50 were found primarily in the cellular pellet fraction after both acute and chronic hyperthermia. SDH completely inhibited 35S-labeling of both HSP60 and HSP50. Labeling of GP50 with 3H-D-mannose was also completely inhibited by SDH. Moreover, SDH progressively reduced N-acetylgalactosaminyl-transferase activity. The data demonstrate that heat sensitization by SDH is accompanied by complex and selectively inhibitory patterns of HSP synthesis and protein glycosylation. Profound inhibition of HSP110, HSP60, and HSP50/GP50 labeling suggests that these may be associated with mechanisms of SDH sensitization.     

Radiobiological characterization of human tumor cell multilayers after conventional and particle irradiation

The goal of this study was to establish planar multilayers from human tumor cells (WiDr and SiHa) as a model for irradiation of solid tumors. In addition to using conventional X rays (250 kV) as a reference standard, multilayers were tested for their suitability in cell survival studies with heavy-ion irradiation ((12)C(6+)) in the plateau and the extended Bragg peak with a scanned ion beam. Multilayers of both cell lines showed decreased survival compared to the corresponding monolayers after both X and heavy-ion irradiation. This multicellular sensitization effect is in contrast to the multicellular resistance or contact effect commonly described in the literature. Flow cytometry measurements showed an arrest of irradiated SiHa cells in G(2)/M phase. In contrast to the transient arrest of the monolayers, the multilayers stayed in a prolonged arrest. After Bragg-peak irradiation of monolayers, the arrest time was increased by 12-24 h, and more cells were arrested than with X rays. For multilayers, there were no differences between G(2) arrest after X rays and heavy ions for the entire observation period.     

Effect of cycloheximide or puromycin on induction of thermotolerance by sodium arsenite in Chinese hamster ovary cells: involvement of heat shock proteins

After sodium arsenite (100 microM) treatment, the synthesis of three major heat shock protein families (HSPs; Mr = 110,000, 87,000, and 70,000), as studied with one-dimensional gels, was enhanced twofold relative to that of unheated cells. The increase of unique HSPs, if studied with two-dimensional gels, would probably be much greater. In parallel, thermotolerance was observed as a 100,000-fold increase in survival from 10(-6) to 10(-1) after 4 hr at 43 degrees C, and as a thermotolerance ratio (TTR) of 2-3 at 10(-3) isosurvival for heating at 45.5 degrees C. Cycloheximide (CHM: 10 micrograms/ml) or puromycin (PUR: 100 micrograms/ml), which inhibited total protein synthesis and HSP synthesis by 95%, completely suppressed the development of thermotolerance when either drug was added after sodium arsenite treatment and removed prior to the subsequent heat treatment. Therefore, thermotolerance induced by arsenite treatment correlated with an increase in newly synthesized HSPs. However, with or without arsenite treatment, CHM or PUR added 2-6 hr before heating and left on during heating caused a 10,000-100,000-fold enhancement of survival when cells were heated at 43 degrees C for 4 hr, even though very little synthesis of heat shock proteins occurred. Moreover, these cells manifesting resistance to heating at 43 degrees C after CHM treatment were much different than those manifesting resistance to 43 degrees C after arsenite treatment. Arsenite-treated cells showed a great deal of thermotolerance (TTR of about 10) when they were heated at 45 degrees C after 5 hr of heating at 43 degrees C, compared with less thermotolerance (TTR of about 2) for the CHM-treated cells heated at 45 degrees C after 5 hr of heating at 43 degrees C. Therefore, there are two different phenomena. The first is thermotolerance after arsenite treatment (observed at 43 degrees C or 45.5 degrees C) that apparently requires synthesis of HSPs. The second is resistance to heat after CHM or PUR treatment before and during heating (observed at 43 degrees C with little resistance at 45.5 degrees C) that apparently does not require synthesis of HSPs. This phenomenon not requiring the synthesis of HSPs also was observed by the large increase in thermotolerance to 45 degrees C caused by heating at 43 degrees C, with or without CHM, after cells were incubated for 6 hr following arsenite pretreatment. For both phenomena, a model based on synthesis and redistribution of HSPs is presented.     

Cold-shock and the Mammalian cell cycle

Progression through the cell cycle is temperature sensitive, but the relationship is not straightforward. In culture, many types of mammalian cells fail to undergo the G(2)/M transition after cooling from 37 degrees C to 16-20 degrees C (moderate hypothermia). However, progression through G(1) and S is not blocked at these temperatures, nor is progression through mitosis in cells cooled after they have become committed to the division process. Thus, at least one pathway is present during G(2)-but not during G(1), S or mitosis-that is selectively disrupted at or below a critical temperature. As a result, a prolonged (24-48 hr) exposure to moderate hypothermia can be used to enrich cultures for G(2) cells. A brief (1 hr) exposure to severe hypothermia (4-10 degrees C) is also reported to induce a high degree of mitotic synchrony (up to 80%) in some mammalian cultures. Although the mechanism behind this synchronization remains vague, it may involve a cell cycle checkpoint, triggered in response to the cold shock, that transiently inhibits the G(1)/S transition.