Evidence for a role of heat-shock proteins in proliferation after heat treatment of synchronized mouse neuroblastoma cells

A role for heat-shock proteins (HSPs) in proliferation after heat treatment was considered in synchronized mouse neuroblastoma cells. For this purpose enhancement of HSP synthesis after heat treatment was inhibited by actinomycin D and the effect of this on cell cycle progression into mitosis and on cell survival was studied both in thermoresistant G1- and in thermosensitive late S/G2-phase cells. In G1-phase cells expression of basal and heat-induced HSP synthesis was the same as that in late S/G2-phase cells, which suggests that regulation of thermoresistance throughout the cell cycle is not directly linked with HSP synthesis. The synthesis of HSP36, HSP68, and HSP70 was enhanced after a 30-min treatment at 41-43 degrees C. Increase of HSP synthesis after heat shock was partly suppressed by the presence of 0.1 microgram/ml actinomycin D during heat treatment, while 0.2 micrograms/ml prevented enhancement of HSP synthesis completely. Suppression of heat-induced HSP synthesis by actinomycin D had the same concentration dependency in G1- and late S/G2-phase cells. Actinomycin D potentiated induction of mitotic delay by heat treatment (30 min, 42.5 degrees C) but only under conditions where it actually inhibited heat-induced enhancement of HSP synthesis. Heat-induced cell killing was also potentiated by actinomycin D. The potentiating effect of actinomycin D on heat-induced mitotic delay and on heat-induced cell killing was more pronounced in G1-phase cells than in late S/G2-phase cells. These results give evidence for a role of HSPs in the resumption of proliferation after heat treatment and suggest that heated G1-phase cells are more dependent on HSP synthesis for recovery of proliferation after heat treatment than heated late S/G2-phase cells.     

Repair in Schizosaccharomyces pombe as measured by recovery from caffeine enhancement of radiation-induced lethality.

Inhibition of DNA repair by caffeine is manifested in Schizosaccharomyces pombe wild-type cells as an enhancement of UV- or gamma-irradiation-induced lethality. The progress of DNA repair processes involving one or more caffeine-sensitive steps may be conveniently followed by measuring the concomitant decrease of this lethal enhancement effect. By measuring, during post-irradiation incubation, the ability of cells to overcome susceptibility to repair inhibition by caffeine, we have determined the time course and requirements for repair in S. pombe. Recovery began immediately and took 150-200 min after gamma-irradiation and more than 500 min after UV-irradiation, for exposures which gave about 10% survival in the absence of caffeine. An incubation medium capable of supporting growth was required for caffeine-sensitive repair; no recovery occurred under liquid holding conditions. Survival curves after various recovery times indicated that a logarithmic phase cell population was homogeneous with respect to caffeine-sensitive repair of both UV- and gamma-ray-induced damage. Recovery from caffeine inhibition was compared for cells of different physiological states (logarithmic and stationary phase); although the importance of the physiological state was not the same for the two types of radiation, recovery was found to occur more rapidly in the more radiation-resistant state, in each case.     

CDC37 is required for p60v-src activity in yeast.

Mutations in genes encoding the molecular chaperones Hsp90 and Ydj1p suppress the toxicity of the protein tyrosine kinase p60v-src in yeast by reducing its levels or its kinase activity. We describe isolation and characterization of novel p60v-src-resistant, temperature-sensitive cdc37 mutants, cdc37-34 and cdc37-17, which produce less p60v-src than the parental wild-type strain at 23 degrees C. However, p60v-src levels are not low enough to account for the resistance of these strains. Asynchronously growing cdc37-34 and cdc37-17 mutants arrest in G1 and G2/M when shifted from permissive temperatures (23 degrees C) to the restrictive temperature (37 degrees C), but hydroxyurea-synchronized cdc37-34 and cdc37-17 mutants arrest in G2/M when released from the hydroxyurea block and shifted from 23 to 37 degrees C. The previously described temperature-sensitive cdc37-1 mutant is p60v-src-sensitive and produces wild-type amounts of p60v-src at permissive temperatures but becomes p60v-src-resistant at its restrictive temperature, 38 degrees C. In all three cdc37 mutants, inactivation of Cdc37p by incubation at 38 degrees C reduces p60v-src-dependent tyrosine phosphorylation of yeast proteins to low or undetectable levels. Also, p60v-src levels are enriched in urea-solubilized extracts and depleted in detergent-solubilized extracts of all three cdc37 mutants prepared from cells incubated at the restrictive temperature. These results suggest that Cdc37p is required for maintenance of p60v-src in a soluble, biologically active form.     

Ligase-deficient yeast cells exhibit defective DNA rejoining and enhanced gamma ray sensitivity.

Yeast cells deficient in DNA ligase were also deficient in their capacity to rejoin single-strand scissions in prelabeled nuclear DNA. After high-dose-rate gamma irradiation (10 and 25 krads), cdc9-9 mutant cells failed to rejoin single-strand scissions at the restrictive temperature of 37 degrees C. In contrast, parental (CDC9) cells (incubated with mutant cells both during and after irradiation) exhibited rapid medium-independent DNA rejoining after 10 min of post-irradiation incubation and slower rates of rejoining after longer incubation. Parental cells were also more resistant than mutant cells to killing by gamma irradiation. Approximately 2.5 +/- 0.07 and 5.7 +/- 0.6 single-strand breaks per 10(8) daltons were detected in DNAs from either CDC9 or cdc9-9 cells converted to spheroplasts immediately after 10 and 25 krads of irradiation, respectively. At the permissive temperature of 23 degrees C, the cdc9-9 cells contained 2 to 3 times the number of DNA single-strand breaks as parental cells after 10 min to 4 h of incubation after 10 krads of irradiation, and two- to eightfold more breaks after 10 min to 2.5 h of incubation after 25 krads of irradiation. Rejoining of single-strand scissions was faster in medium. After only 10 min in buffered growth medium and after 10 krads of irradiation, the number of DNA single-strand breaks was reduced to 0.32 +/- 0.3 (at 23 degrees C) or 0.21 +/- 0.05 (at 37 degrees C) per 10(8) daltons in parental cells, but remained at 2.1 +/- 0.06 (at 23 degrees C) or 2.3 +/- 0.07 (at 37 degrees C) per 10(8) daltons in mutant cells. After 10 or 25 krads of irradiation plus 1 h of incubation in medium at 37 degrees C, only DNA from CDC9 cells was rejoined to the size of DNA from unirradiated cells, whereas at 23 degrees C, DNAs in both strains were completely rejoined.     

Effect of temperature on hybridoma cell cycle and MAb production

The kinetics of growth and antibody formation of an anti-interleukin-2 producing hybridoma line were studied in suspension culture at temperatures ranging from 34 degrees C to 39 degrees C. Flow cytometry was used to determine the effect of temperature on the cell cycle. Maximum cell density and monoclonal antibody yield were observed at 37 degrees C. The specific monoclonal antibody production rate was approximately constant throughout each batch experiment. Lower temperatures caused cells to stay longer in the G(1)-phase of the cell cycle, but temperature had only a marginal effect on the specific antibody production rate. Arresting of cells in the G(1)-phase by means of temperature was, therefore, not suited for enhanced monoclonal antibody production. Rather, antibody production for this hybridoma was directly linked to viable cell concentration. (c) 1992 John Wiley & Sons, Inc.     

Splicing thermotolerance maintains pre-mRNA transcripts in the splicing pathway during severe heat shock

Thermotolerance, the ability of cells and organisms to withstand severe elevated temperatures after brief exposure to mild elevated temperatures, has been studied in numerous laboratories. Survival thermotolerance is defined as the increase in cell or organism survival at severe elevated temperatures after a pretreatment at mild elevated temperatures. This study examines splicing thermotolerance in Drosophila melanogaster, the ability to splice pre-mRNAs made at the severe temperature (38 degrees C) after a brief pretreatment at a milder temperature (35 degrees C). It is probably one of a number of mechanisms by which cells adapt to heat shock. These experiments demonstrate that pre-mRNAs synthesized at the severe temperatures in splicing thermotolerant cells, although protected in splicing-competent complexes, are not actually processed to mature mRNAs until the cells are returned to their normal temperature. We have also studied the kinetics of acquisition and loss of splicing thermotolerance. As little as 10 min of pretreatment at 35 degrees C was sufficient to provide full splicing thermotolerance to a 30-min severe heat shock of 38 degrees C. Pretreatments of less than 10 min provide partial splicing thermotolerance for a 30-min severe heat shock. Full splicing thermotolerance activity begins to decay about 4 h after the cessation of the 35 degrees C incubation and is completely lost by 8 h after the pretreatment. The kinetics experiments of pre-mRNAs synthesized during the 38 degrees C treatment in splicing thermotolerant cells indicate that one or more splicing thermotolerance factors are synthesized during the 35 degrees C pretreatment which interact with pre-mRNA-containing complexes to keep them in a splicing-competent state. These kinetic experiments also indicate that in cells which are partially splicing thermotolerant, the pre-mRNAs synthesized early during the 38 degrees C incubation are protected, whereas those synthesized late are not. In the absence of splicing thermotolerant factors, the pre-mRNA-containing complexes leave the normal splicing pathway and are allowed to exit to the cytoplasm.     

Reduction of radiation-induced cell cycle blocks by caffeine does not necessarily lead to increased cell killing

The effect of caffeine upon the radiosensitivities of three human tumor lines was examined and correlated with its action upon the radiation-induced S-phase and G2-phase blocks. Caffeine was found to reduce at least partially the S-phase and G2-phase blocks in all the cell lines examined but potentiated cytotoxicity in only one of the three tumor lines. That reductions have been demonstrated to occur in the absence of increased cell killing provides supporting evidence for the hypothesis that reductions may not be causal in those cases when potentiation of radiation-induced cytotoxicity is observed in the presence of caffeine.     

Hyperthermic killing and hyperthermic radiosensitization in Chinese hamster ovary cells: effects of pH and thermal tolerance

To quantitatively relate heat killing and heat radiosensitization, asynchronous or G1 Chinese hamster ovary (CHO) cells at pH 7.1 or 6.75 were heated and/or X-irradiated 10 min later. Since no progression of G1 cells into S phase occurred during the heat and radiation treatments, cell cycle artifacts were minimized. However, results obtained for asynchronous and G1 cells were similar. Hyperthermic radiosensitization was expressed as the thermal enhancement factor (TEF), defined as the ratio of the D0 of the radiation survival curve to that of the D0 of the radiation survival curve for heat plus radiation. The TEF increased continuously with increased heat killing at 45.5 degrees C, and for a given amount of heat killing, the amount of heat radiosensitization was the same for both pH's. When cells were heated chronically at 42.4 degrees C at pH 7.4, the TEF increased initially to 2.0-2.5 and then returned to near 1.0 during continued heating as thermal tolerance developed for both heat killing and heat radiosensitization. However, the shoulder (Dq) of the radiation survival curve for heat plus radiation did not manifest thermal tolerance; i.e., it decreased continuously with increased heat killing, independent of temperature, pH, or the development of thermotolerance. These results suggest that heat killing and heat radiosensitization have a target(s) in common (TEF results), along with either a different target(s) or a difference in the manifestation of heat damage (Dq results). For clinical considerations, the interaction between heat and radiation was expressed as (1) the thermal enhancement ratio (TER), which is the dose of X rays alone divided by the dose of X rays combined with heat to obtain an isosurvival, e.g., 10(-4), and (2) the thermal gain factor (TGF), the ratio of the TER at pH 6.75 to the TER at pH 7.4. Since low pH reduced the rate of development of thermal tolerance during heating at low temperatures, low pH enhanced heat killing more at 42-42.5 degrees C than at 45.5 degrees C where thermal tolerance did not develop. Therefore, the increase in the TGF after chronic heating at 42-42.5 degrees C was greater than after acute heating at 45.5 degrees C, due primarily to the increase in heat killing causing an even greater increase in heat radiosensitization. These findings agree with animal experiments suggesting that in the clinic, a therapeutic gain for tumor cells at low pH may be greater for temperatures of 42-42.5 degrees C than of 45.5 degrees C.     

Relationship of chromosomal damage induced by caffeine to growth temperature and ATP level in proliferating cells

Caffeine is known to induce chromosomal aberrations in proliferating cells when they are incubated during G2 and mitotic prophase. In the present paper, this caffeine effect has been analyzed in Allium cepa root meristems growing at different culture temperatures under steady-state kinetics. Caffeine (1-10 mM) induces chromosomal aberrations in a dose-dependent manner, and the treatment efficiency correlates linearly with the square of caffeine concentration. The efficiency of caffeine incubations, within the range 5-25 degrees C during equivalent cycle time periods has also been studied. It has been found that the lower the culture temperature, the higher the level of chromosomal aberrations. Moreover, at different temperatures, the level of chromosomal aberrations is a simple function of caffeine concentration and the ATP level. Therefore, the efficiency of caffeine treatment appears to be determined by some interaction between caffeine concentration and cellular ATP level. Our present results demonstrate that the influence of growth temperature on the chromosome-breaking effect of caffeine can be, at least partially, explained by the ATP levels during the incubation periods. In short, under different kinetics of plant cell proliferation, the ATP level, and/or something correlating with it, could explain the efficiency of caffeine in inducing chromosomal aberrations: the lower the ATP level, the higher the caffeine efficiency.     

Influence of postirradiation incubation temperature on recovery of radiation-injured Clostridium botulinum 62A spores.

The number of colonies formed by unirradiated Clostridium botulinum 62A spores was independent of temperature, in the range from 20 to 45 degrees C (in 5 degrees C increments); no colonies developed at 50 degrees C. Spores irradiated at 1.2 or 1.4 Mrads produced more macrocolonies at 40 degrees C than at higher or lower temperatures. Apparently, radiation-injured spores were capable of repair of 40 degrees C than at the other temperatures studied. More than 99% of the radiation (1.2 Mrads) survivors were injured and were unable to form macrocolonies in the presence of 5% NaCl. The germinated radiation-injured spores were also sensitive to dilution, resulting in the loss of viability of 77 to 79% of the radiation survivors. At 30 and 40 degrees C, the irradiated spores did not differ significantly in the extent of germination (greater than 99% at both 30 and 40 degrees C), emergence (64% at 30 degrees C and 67% at 40 degrees C), and the maximum number of emerged cells that started to elongate (69% at 30 degrees C and 79% at 40 degrees C). However, elongation was remarkably more extensive at 40 degrees C than at 30 degrees C. Many elongated cells lysed within 48 h at 30 degrees C, indicating an impaired repair mechanism. If the radiation-injured spores were incubated at 40 degrees C in the recovery (repair) medium for 8 to 10 h, they germinated, emerged, and elongated extensively and were capable of repair. If, after 8 to 10 h at 40 degrees C, these cultures were shifted to 30 degrees C, the recovery at 30 increased by more than eightfold, resulting in similar colony counts at 30 and 40 degrees C. Thus, repair appeared to be associated with outgrowth. Repair did not occur in the presence of chloramphenicol at 40 degrees C, whereas penicillin had no effect, suggesting that the repair involved protein synthesis but did not require multiplication.     

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.     

Caffeine eliminates gamma-ray-induced G2-phase delay in human tumor cells but not in normal cells.

It has been known for many years that caffeine reduces or eliminates the G2-phase cell cycle delay normally seen in human HeLa cells or Chinese hamster ovary (CHO) cells after exposure to X or gamma rays. In light of our recent demonstration of a consistent difference between human normal and tumor cells in a G2-phase checkpoint response in the presence of microtubule-active drugs, we examined the effect of caffeine on the G2-phase delays after exposure to gamma rays for cells of three human normal cell lines (GM2149, GM4626, AG1522) and three human tumor cell lines (HeLa, MCF7, OVGI). The G2-phase delays after a dose of 1 Gy were similar for all six cell lines. In agreement with the above-mentioned reports for HeLa and CHO cells, we also observed that the G2-phase delays were eliminated by caffeine in the tumor cell lines. In sharp contrast, caffeine did not eliminate or even reduce the gamma-ray-induced G2-phase delays in any of the human normal cell lines. Since caffeine has several effects in cells, including the inhibition of cAMP and cGMP phosphodiesterases, as well as causing a release of Ca(++) from intracellular stores, we evaluated the effects of other drugs affecting these processes on radiation-induced G2-phase delays in the tumor cell lines. Drugs that inhibit cAMP or cGMP phosphodiesterases did not eliminate the radiation-induced G2-phase delay either separately or in combination. The ability of caffeine to eliminate radiation-induced G2-phase delay was, however, partially reduced by ryanodine and eliminated by thapsigargin, both of which can modulate intracellular calcium, but by different mechanisms. To determine if caffeine was acting through the release of calcium from intracellular stores, calcium was monitored in living cells using a fluorescent calcium indicator, furaII, before and after the addition of caffeine. No calcium release was seen after the addition of caffeine in either OVGI tumor cells or GM2149 normal cells, even though a large calcium release was measured in parallel experiments with ciliary neurons. Thus it is likely that caffeine is eliminating the radiation-induced G2-phase delay through a Ca(++)-independent mechanism, such as the inhibition of a cell cycle-regulating kinase.     

The effects of temperature upon the electrophysiological properties of Tetrahymena pyriformis-NT1

Cells of Tetrahymena pyriformis--NT1 were cultured at 38 degrees C (Tg 38 degrees C) and 20 degrees C (Tg 20 degrees C) and their properties investigated over the range 0-40 degrees C. Tg 20 degrees C cells were viable in the range 3-33 degrees C and changes in their properties were readily reversible between 10 degrees C and 30 degrees C. Tg 38 degrees cells were viable in the range 40-10 degrees C and their property changes were immediately reversible in the range 40-23 degrees C. The I-V relations of Tg 38 degrees C cells showed increased excitability as the cells were cooled from 40 degrees C. At 10 degrees C there was a considerable loss of excitability and slope resistance. Cooling Tg 20 degrees C cells from 20 degrees C gave a similar pattern, although over a narrower temperature range. Warming Tg 20 degrees C Tetrahymena above 20 degrees C led to a progressive loss of excitability and the cells were markedly less viable above 35 degrees C. Within physiological limits the regenerative spike magnitude, repolarization time, time to peak and input resistance increased as temperature was lowered, whereas resting potential was diminished. When compared at their growth temperatures and most intermediate temperatures, the value of the various parameters monitored were generally different for the two cultures. The Q10 value for resting potential changes of Tg 20 degrees C cells about 20 degrees C was 1.20. As in T. vorax this was significantly (P less than 0.01) greater than that predicted for a diffusion potential and suggested that T. pyriformis--NT1 may have an electrogenic pump component in its membrane potential.     

Complement attack of altered outer membrane areas synthesized after inhibition of the 3-deoxy-D-manno-octulosonate pathway leads to cell death

Salmonella typhimurium containing specific genes coding for either temperature-sensitive (TS) 3-deoxy-D-manno-octulosonate (KDO) 8-phosphate synthetase or TS cytidine monophosphate-KDO synthetase grow normally when incubated at 30 degrees C and are resistant to C-mediated killing. However, bacteria become avirulent and sensitive to C-mediated killing upon thermal inhibition of TS KDO-8-phosphate synthetase (incubation at 38 degrees C) or TS cytidine monophosphate-KDO synthetase (incubation at 42 degrees C). Such thermal inhibition concurrently causes synthesis of an altered outer membrane which we now show is the site that renders cells susceptible to C-mediated killing. After incubation of cells in serum, the altered outer membrane area contains C9 in a trypsin-resistant state and membrane attack complex (MAC) lesions observable by electron microscopy. Trypsin-resistant C9 and MAC lesions were also observed in the inner membrane fraction from such serum-treated cells. In contrast, little C9 and few MAC lesions were associated with unaltered outer membrane areas present on these same serum treated cells. Control cells, grown at 30 degrees C and treated with serum (1) bound one-fifth as much C9 as was bound to cells incubated at 42 degrees C, (2) contained only a rare MAC lesion in the outer membrane, and (3) no observable MAC lesions in the inner membrane. We conclude that the altered outer membrane area is the site that renders cells susceptible to insertion of the MAC into both the outer and inner membrane resulting in cell death.     

A phospholipid-deacylating system of bacteria active in a frozen medium.

A phosphatidylcholine-deacylating system present in a Butyrivibrio species (probably fibrisolvens) shows appreciable activity at low temperatures with a maximum hydrolysis rate at--10 degrees C. 2. The rate at--10 degrees C is higher than at 39 degrees C unless the system at the latter temperature is stimulated by adding oleic acid or sodium dodecyl sulphate. 3. The low-temperature phospholipase activity has an absolute requirement for thiol reagents, e.g. cysteine, dithiothreitol or mercaptoethanol. 4. Ca2+, Mg2+ and Mn2+ stimulate the activity up to 10 mM, but EDTA inhibits; higher concentrations of Ca2+ also inhibit. 5. The enhancement of activity at low temperatures appears not to be associated with a crystalline change in the hydrated phospholipid substrate, but depends on the formation of a solid phase in the incubation medium which brings the substrate and bacterial cells into juxtaposition or causes fusion.     

Growth of and toxin production by nonproteolytic Clostridium botulinum in cooked puréed vegetables at refrigeration temperatures.

Seven strains of nonproteolytic Clostridium botulinum (types B, E, and F) were each inoculated into a range of anaerobic cooked puréed vegetables. After incubation at 10 degrees C for 15 to 60 days, all seven strains formed toxin in mushrooms, five did so in broccoli, four did so in cauliflower, three did so in asparagus, and one did so in kale. Growth kinetics of nonproteolytic C. botulinum type B in cooked mushrooms, cauliflower, and potatoes were determined at 16, 10, 8, and 5 degrees C. Growth and toxin production occurred in cooked cauliflower and mushrooms at all temperatures and in potatoes at 16 and 8 degrees C. The C. botulinum neurotoxin was detected within 3 to 5 days at 16 degrees C, 11 to 13 days at 10 degrees C, 10 to 34 days at 8 degrees C, and 17 to 20 days at 5 degrees C.     

Time-temperature analyses of cell killing of synchronous G1 and S phase Chinese hamster cells in vitro

Time-temperature analyses of durations of heating required to achieve isosurvival were used to compare hyperthermic cell killing of synchronous Chinese hamster ovary (CHO) cells heated in G1 or S at temperatures of 42 to 45.5 degrees C. G1 populations were obtained by incubation of mitotic cells for 90 min at 37 degrees C. S phase populations were obtained by incubation of mitotic cells for 12 h at 37 degrees C in medium supplemented with 2 micrograms/ml aphidicolin, a reversible inhibitor of DNA alpha polymerase; S phase survival was also determined in an aphidicolin-free system by using high specific activity [3H]thymidine. In both systems, the thermosensitivity was similar and decreased as the cells progressed from early S phase, in agreement with earlier studies (R. A. Read, M. H. Fox, and J. S. Bedford. Radiat. Res. 98, 491-505 (1984]. A comparison of Arrhenius plots of the inverse of durations of heating required to achieve isosurvival for cells heated in G1 or S phase showed similar temperature dependence above 43.5 degrees C, yet the plots for heat-sensitive S phase cells were offset from those for heat-resistant G1 cells by about 1.5 degrees C, i.e., S phase cells respond to 43 degrees C with a rate similar to that observed in G1 cells heated at 44.5 degrees C. Using least-squares regression of the semilog plots, the curves were analyzed either as continually bending curves or as two straight lines with a break at 43.5 degrees C. When the data were analyzed using two straight lines, no significant differences in the slopes of the time-temperature plots of G1 or S phase cells were observed. A quantitative comparison between the two methods of data analysis demonstrated that in both phases the data were better fit with a continuously curving line, rather than two straight lines.     

The action of caffeine on X-irradiated HeLa cells. X. Depressed recovery from potentially lethal damage in cells containing 5-bromodeoxyuridine

HeLa S3 cells were sensitized to the lethal action of 220-kV X rays by partially replacing the thymidine in their DNA with 5-bromodeoxyuridine (BrdU). To examine the expression of and recovery from potentially lethal radiation damage (PLD), both BrdU-grown and control cells were treated with 4 mM caffeine for increasing times up to 2 days, either immediately after irradiation or after increasing delays up to 28 h. When the same dose of X rays (3 Gy) was applied to BrdU-grown and control cells, the difference in survival that is found in the absence of caffeine disappeared after about 30 h of incubation in its presence; when isosurvival doses were applied (BrdU-grown cells, 2.5 Gy; control cells, 4 Gy), the control cells suffered more killing. When treatment with caffeine was delayed for progressively longer times after both groups of cells received 3 Gy, the control cells achieved a higher level of survival. These results indicate that the increased radiation sensitivity of cells containing BrdU derives from a decreased ability to repair PLD.     

Influence of the sporulation temperature upon the heat resistance of Bacillus subtilis.

The influence of different sporulation temperatures (30, 37, 44 and 52 degrees C) upon heat resistance of Bacillus subtilis was investigated. Heat resistance was greater after higher sporulation temperatures. Relation of heat resistance and temperature of sporulation was not linear over all the range of temperatures tested. Heat resistance increased about tenfold in the range of 30-44 degrees C. Sporulation at 52 degrees C did not show any further increase in heat resistance. This effect was constant over all the range of heating temperatures tested (100-120 degrees C). z value remained constant (z = 9 degrees C). Greater heat resistances at higher temperatures of sporulation were not due to selection of more heat resistant cells by a higher sporulation temperature. Spores obtained from cells incubated at 32 or 52 degrees C always possessed heat resistances that corresponded to the sporulation temperature regardless of the incubation temperature of their vegetative cells.