Repair of DNA Strand Breaks at Hyperthermic Temperatures in Chinese Hamster Ovary Cells

The repair of DNA double-strand breaks was measured by pH 7.2 filter elution in cells incubated at 25-45 degrees C either before or after X-irradiation. Exposure to 45 degrees C for 15 minutes immediately prior to X-irradiation significantly increased both the half-time for DNA double-strand break closure and the number of DNA double-strand breaks remaining in nuclear DNA 180 minutes after irradiation. Exposure to temperatures between 41 and 45 degrees C immediately after X-irradiation accelerated DNA double-strand break closure and resulted in no increase in the number of DNA double-strand breaks remaining in the cell's genome 180 minutes after irradiation. The results indicate either that the radiosensitization produced by the administration of hyperthermic temperatures before and after irradiation result from two characteristically different molecular mechanisms, or that neither the rate of DNA strand break closure nor the number of DNA strand breaks remaining in nuclear DNA after irradiation accurately predict hyperthermic radiosensitization. These conclusions assume that no DNA strand breaks are below the resolution of this DNA damage assay and that a comparison between cytotoxicity and DNA repair after exposure to high radiation doses is valid.

Accumulation, activation and interindividual variation of the epidermal TP53 protein in response to ionizing radiation in organ cultured human skin

In this study, we examined effects of low-dose ionizing radiation on organ cultured human foreskin and, in particular, on the epidermis. Diagnostic, therapeutic, natural environmental and incidental exposures to moderate to low doses of radiation are inevitable and, although information on cultured cells continues to accumulate, little is known about the effects of low-dose radiation on human tissues. Our hypothesis is that ex vivo organ cultured foreskin is a simple and reliable model to study the biochemical effects of low-dose radiation exposure on skin. A model such as this will aid in the identification and quantification of low-dose radiation-induced changes in proteins in human skin and may be useful in the development of a precise, non-invasive, and reliable assay of exposure. In this work, several aspects of skin responses to culture conditions and radiation were examined. The responses of epidermal TP53 from organ cultured skin irradiated in medium with and without serum were found to be similar. TP53 levels in organ cultured neonatal foreskin epidermis were then examined for baseline TP53 expression. After an initial increase at 4 h, the TP53 D01 signal returned to low steady-state levels for at least 72 h. Irradiated skin samples from different individuals revealed variations in the TP53 D01 signal. The dose and temporal response of dermis and epidermis to radiation were examined by Western blotting from 0 to 24 h after exposure. After irradiation and incubation, the epidermis was removed and assayed by Western blotting and was found to have increases in the TP53 D01 epitope and the TP53 phosphoserine 15 (TP53-S15p) epitope that reached a maximum at about 3 h. In the epidermis, doses of 1-5 cGy of radiation were detectable with the TP53 D01, and CDKN1A antibodies and doses greater than 10 cGy were detectable with the TP53-S15p antibody. When the dermis was compared to epidermis, it was found that dermis had a smaller response to radiation and more phosphorylated TP53.

Thiazolidine prodrugs as protective agents against gamma-radiation-induced toxicity and mutagenesis in V79 cells

Representatives of two classes of thiazolidine prodrug forms of the well-known radioprotective agents L-cysteine, cysteamine, and 2-[(aminopropyl)amino]ethanethiol (WR-1065) were synthesized by condensing the parent thiolamine with an appropriate carbonyl donor. Inherent toxicity of the prodrugs was assessed in V79 cells using a clonogenic survival assay. Protection against radiation-induced cell death was measured similarly after exposure to 0--8 Gy gamma ((137)Cs) radiation. Antimutagenic activity was determined at the hypoxanthine-guanine phosphoribosyltransferase (HGPRT) locus. All thiazolidine prodrugs exhibited less toxicity than their parent thiolamines, sometimes dramatically so. Protection against radiation-induced cell death was observed for the 2-alkylthiazolidine, 2(R,S)-D-ribo-(1',2',3',4'-tetrahydroxybutyl)thiazolidine (RibCyst), which produced a protection factor at 8 Gy of 1.8; the cysteine analogue, 2(R,S)-D-ribo-(1',2',3',4'-tetrahydroxybutyl)thiazolidine-4(R)-carboxylic acid (RibCys), was less active. RibCyst also exhibited excellent antimutational activity, rivaling that of WR-1065. The 2-oxothiazolidine analogues showed little activity in either determination under the conditions tested, perhaps due to their enhanced chemical and biochemical stability.

The nuclear matrix is a thermolabile cellular structure

Heat shock sensitizes cells to ionizing radiation, cells heated in S phase have increased chromosomal aberrations, and both Hsp27 and Hsp70 translocate to the nucleus following heat shock, suggesting that the nucleus is a site of thermal damage. We show that the nuclear matrix is the most thermolabile nuclear component. The thermal denaturation profile of the nuclear matrix of Chinese hamster lung V79 cells, determined by differential scanning calorimetry (DSC), has at least 2 transitions at Tm = 48 degrees C and 55 degrees C with an onset temperature of approximately 40 degrees C. The heat absorbed during these transitions is 1.5 cal/g protein, which is in the range of enthalpies for protein denaturation. There is a sharp increase in 1-anilinonapthalene-8-sulfonic acid (ANS) fluorescence with Tm = 48 degrees C, indicating increased exposure of hydrophobic residues at this transition. The Tm = 48 degrees C transition has a similar Tm to those predicted for the critical targets for heat-induced clonogenic killing (Tm = 46 degrees C) and thermal radiosensitization (Tm = 47 degrees C), suggesting that denaturation of nuclear matrix proteins with Tm = 48 degrees C contribute to these forms of nuclear damage. Following heating at 43 degrees C for 2 hours, Hsc70 binds to isolated nuclear matrices and isolated nuclei, probably because of the increased exposure of hydrophobic domains. In addition, approximately 25% of exogenous citrate synthase also binds, indicating a general increase in aggregation of proteins onto the nuclear matrix. We propose that this is the mechanism for increased association of nuclear proteins with the nuclear matrix observed in nuclei Isolated from heat-shocked cells and is a form of indirect thermal damage.

Effects of modifying topoisomerase II levels on cellular recovery from radiation damage

Effects of Modifying Topoisomerase II Levels on Cellular Recovery from Radiation Damage. Experiments were performed with the budding yeast, Saccharomyces cerevisiae, to test whether DNA topoisomerase II is involved in repair of DNA damage induced by ionizing radiation. Topoisomerase II was inactivated by use of a temperature-sensitive mutation. Enzyme inactivation increased cellular radiosensitivity, blocked the restitution of broken chromosomes, assayed by pulsed-field gel electrophoresis, and prolonged the induction of a DNA damage-inducible gene (RNR3). Overexpression of the topoisomerase II gene did not alter cellular radiosensitivity. The data support a role for topoisomerase II in the repair of DNA strand breaks.

Radioprotective thiolamines WR-1065 and WR-33278 selectively denature nonhistone nuclear proteins

Differential scanning calorimetry was used to study the interactions of nuclei isolated from Chinese hamster V79 cells with the radioprotector WR-1065, other thiol compounds, and polyamines. Differential scanning calorimetry monitors denaturation of macromolecules and resolves the major nuclear components (e.g. constrained and relaxed DNA, nucleosome core, and nuclear matrix) of intact nuclei on the basis of thermal stability. WR-1065 treatment (0.5-10 mM) of isolated nuclei led to the irreversible denaturation of nuclear proteins, a fraction of which are nuclear matrix proteins. Denaturation of 50% of the total nonhistone nuclear protein content of isolated nuclei occurred after exposure to 4.7 mM WR-1065 for 20 min at 23 degrees C. In addition, a 22% increase in the insoluble protein content of nuclei isolated from V79 cells that had been treated with 4 mM WR-1065 for 30 min at 37 degrees C was observed, indicating that WR-1065-induced protein denaturation occurs not only in isolated nuclei but also in the nuclei of intact cells. From the extent of the increase in insoluble protein in the nucleus, protein denaturation by WR-1065 is expected to contribute to drug toxicity at concentrations greater than approximately 4 mM. WR-33278, the disulfide form of WR-1065, was approximately twice as effective as the free thiol at denaturing nuclear proteins. The proposed mechanism for nucleoprotein denaturation is through direct interactions with protein cysteine groups with the formation of destabilizing protein-WR-1065 disulfides. In comparison to its effect on nuclear proteins in isolated nuclei, WR-1065 had only a very small effect on non-nuclear proteins of whole cells, isolated nuclear matrix, or the thiol-rich Ca(2+)ATPase of sarcoplasmic reticulum, indicating that WR-1065 can effectively denature protein only inside an intact nucleus, probably due to the increased concentration of the positively charged drug in the vicinity of DNA.

Radioprotection of human cell nuclear DNA by polyamines: radiosensitivity of chromatin is influenced by tightly bound spermine

The polyamines putrescine (PUT) and spermine (SPM) were examined for their ability to protect human cell DNA against the formation of radiation-induced double-strand breaks (DSBs). As observed previously, under conditions where polyamines were shown to be almost completely absent, association with nuclear matrix protein into a nucleoid, and organization into chromatin structure, protected DNA from induction of DSBs by factors of 4.5 and 95, respectively. At concentrations below 1 mM, PUT or SPM provided equivalent levels of protection to deproteinized nuclear DNA, consistent with their capacity to scavenge radiation-induced radicals. At constant ionic strength, 5 mM SPM protected deproteinized DNA and nucleoid DNA and DNA in nuclear chromatin by factors of 100 and 26, respectively. At 5 mM, SPM provided 15 times greater protection of deproteinized DNA than did PUT. Under physiologically relevant conditions, 5 mM SPM protected DNA in the intact nucleus from the induction of DSBs by a factor of 2 relative to DNA in the absence of SPM. Studies of SPM binding during cellular fractionation revealed that a significant fraction of the cellular SPM is tightly bound in the nucleus but can be removed by extended washing. Thus the association of SPM with nuclear chromatin appears to be a significant contributor to the resistance of the cell's DNA to the induction of DSBs.

Modulation of radiation-induced apoptosis by thiolamines

Exposure to the thiolamine radioprotector N-(2-mercaptoethyl)-1,3-propanediamine (WR-1065) induced apoptosis in the mouse TB8.3 hybridoma after a 60-min (LD50 = 4.5 mM) or during a 20-h (LD50 = 0.15 mM) exposure. In contrast, a 20-h exposure to 17 mM L-cysteine or 10 mM cysteamine was required to induce 50% apoptosis within 20 h. Apoptosis was not induced by either a 60-min or 20-h exposure to 10 mM of the thiazolidine prodrugs ribose-cysteine (RibCys) or ribose-cysteamine (RibCyst). Thiolamine-induced apoptosis appeared to be a p53-independent process since it was induced by WR-1065 exposure in human HL60 cells. Exposure to WR-1065 (4 mM for 15 min) or cysteine (10 mM for 60 min) before and during irradiation protected cells against the induction of both DNA double-strand breaks and apoptosis, while exposure to RibCys (10 mM for 3 h) did not. Treatment with either WR-1065, cysteine, RibCys or RibCyst for 60 min beginning 60 min after irradiation did not affect the level of radiation-induced apoptosis. In contrast, treatment with either cysteine, cysteamine or RibCys for 20 h beginning 60 min after irradiation enhanced radiation-induced apoptosis. Similar experiments could not be conducted with WR-1065 because of its extreme toxicity. Our results indicate that thiolamine enhancement of radiation-induced apoptosis is not involved in their previously reported capacity to reduce radiation-induced mutations.

Free radicals generated by ionizing radiation signal nuclear translocation of p53

The p53 tumor suppressor is a transcription factor that regulates several pathways, which function collectively to maintain the integrity of the genome. Nuclear localization is critical for wild-type function. However, the signals that regulate subcellular localization of p53 have not been identified. Here, we examine the effect of ionizing radiation on the subcellular localization of p53 in two cell lines in which p53 is normally sequestered in the cytoplasm and found that ionizing radiation caused a biphasic translocation response. p53 entered the nucleus 1-2 h postirradiation (early response), subsequently emerged from the nucleus, and then again entered the nucleus 12-24 h after the cells had been irradiated (delayed response). These changes in subcellular localization could be completely blocked by the free radical scavenger, WR1065. By comparison, two DNA-damaging agents that do not generate free radicals, mitomycin C and doxorubicin, caused translocation only after 12-24 h of exposure to the drugs, and this effect could not be inhibited by WR1065. Hence, although all three DNA-damaging agents induced relocalization of p53 to the nucleus, only the translocation caused by radiation was sensitive to free radical scavenging. We suggest that the free radicals generated by ionizing radiation can signal p53 translocation to the nucleus.

Thiazolidine prodrugs of cysteamine and cysteine as radioprotective agents

The need for protection against the toxic effects of ionizing radiation comes from many different directions: occupational exposure, nuclear accidents, environmental sources and protection of normal tissue during the therapeutic irradiation of cancer. Sulfhydryl-containing compounds, including cysteamine and L-cysteine, have long been known to possess radioprotective properties, but their therapeutic utility is limited by their side effects at radioprotective doses. To avoid this drawback, thiazolidine prodrugs of cysteamine and L-cysteine were prepared by the condensation of each thioalmine with the aldose monosaccharides, D-ribose and D-glucose, producing RibCyst, GlcCyst, RibCys and GlcCys. The prodrugs were designed to liberate the parent thiolamine nonenzymatically, after ring opening and hydrolysis, which is then available to function as a radioprotective agent. Cysteamine's inherent toxicity, measured using Chinese hamster V79 cells growing in culture, was completely eliminated, even at concentrations as high as 25 mM, by providing the thiolamine in the form of a prodrug. Good protection against radiation-induced lethality was demonstrated by the cysteamine prodrugs using a clonogenic assay. Protection against radiation-induced DNA single-strand breaks, as measured by alkaline elution, was also shown by both RibCyst and GlcCyst; this activity was higher than that exhibited by either cysteamine or WR-1065. The L-cysteine prodrugs, RibCys and GlcCys, also possessed radioprotective abilities under most of the conditions studied. Protection against DNA damage was comparable between L-cysteine, WR-1065 and RibCys.

DNA double-strand break repair in two radiation-sensitive mouse mammary carcinoma cell lines

The capacity of two radiation-sensitive clones (SX9 and SX10) of the mouse mammary carcinoma cell line SR1 to rejoin radiation-induced DNA double-strand breaks (DSBs) was determined by pulsed-field agarose gel electrophoresis. DSBs were produced with equivalent efficiency in all three cell lines. Both the SX9 and SX10 cell lines demonstrated a significantly diminished capacity to rejoin radiation-induced DSBs. The fraction of the original DNA DSB damage remaining in the DNA of 20 Gy-exposed SR1, SX9 and SX10 cells after 6 h of 37 degrees C incubation was estimated to be 14, 82 and 54%, respectively. In addition the SX10 cell line exhibited enhanced cytotoxicity when exposed to the DNA topoisomerase II poison mitoxantrone. The results indicate that both the SX9 and SX10 cell lines are DNA DSB repair mutants.

Heat sensitivity of HeLa S3 cell DNA topoisomerase II

The sensitivity of HeLa DNA topoisomerase II to 45 degrees C heat shock was measured both in the intact cell and in vitro. In the intact cell, DNA topoisomerase II activity was estimated by measuring the formation and reversal of enzyme-DNA cleavable complexes by alkaline filter elution of cells exposed to the enzyme poison 4'-(9-acridinylamino)methanesulfon-m-anisidide). In vitro enzymatic activity was estimated by measuring changes in the topological state of plasmid and kinetoplast DNA produced by sonicates of nuclei from previously heated cells. The capacity of the enzyme to form, or reverse, enzyme-DNA cleavable complexes was inactivated during 45 degrees C heating with a reciprocal slope of 120 or 15 min, respectively. In vitro estimates of the activity of the enzyme from previously heated cells indicated that the enzyme was inactivated with a reciprocal slope of 99, 45, and 21 min after 45, 46 and 47 degrees C heating, respectively. DNA topoisomerase I activity was inactivated with a reciprocal slope of 130 min at 45 degrees C. The cumulative results indicate that during 45 degrees C heat shock, thermal inactivation of neither DNA topoisomerase I nor II is rate limiting for either cell survival or for DNA replication. While DNA topoisomerase II is resistant in situ to heat inactivation, in vivo assays indicate that the enzyme's capacity to function in the intact cell may be compromised by hyperthermic changes in the enzyme's environment.

Persistence of radiation-induced double-strand breaks in the DNA of heated CHO cells

Chinese hamster ovary cells were either heated at 45 degrees C for 15 min or left unheated immediately prior to irradiation and incubation at 37 or 41 degrees C for 5 h. When cellular DNA was analysed by electrophoresis of double-stranded DNA through agarose gels 5 h after irradiation, DNA fragments presumably resulting from unrepaired DNA double-strand breaks (dsbs) were observed in the DNA of all cells. The frequency of the putative unrepaired dsbs was greater in cells heated at 45 degrees C for 15 min before, or incubated at 41 degrees C for 5 h after irradiation, than in unheated, control cells. Gel electrophoresis results were consistent with a failure of irradiated cells to rejoin dsb completely when heated at 45 degrees C before, or incubated at 41 degrees C for 5 h after irradiation. In contrast, nuclear DNA accessibility studies using either an exogenous or an endogenous endonuclease detected no change in the accessibility of DNA in nuclei from 41 degrees C-heated cells. These DNA accessibility studies indicate that the dsbs observed in the DNA of 41 degrees C-heated cells may not result from an actual failure of irradiated cells to repair radiation-induced dsbs during incubation at 41 degrees C.

Makaluvamines, marine natural products, are active anti-cancer agents and DNA topo II inhibitors

The makaluvamines were isolated from a sponge of the genus Zyzzya by following bioactivity against the human colon carcinoma cell line, HCT 116. These compounds have considerable cytotoxic activity. The makaluvamines appear to be acting through inhibition of DNA topoisomerase II. The compounds show enhanced toxicity toward a topoisomerase II-cleavable complex-sensitive cell line, they inhibit topoisomerase II decatenation of kinetoplast DNA in vitro. Makaluvamine C was shown to produce protein-linked DNA double-strand breaks, and makaluvamine A produced DNA double-strand breaks by neutral filter elution in a dose-dependent fashion similar to 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA). The makaluvamines also increased the life span of nude mice bearing solid tumors of human ovarian cancer cells.

Induction and repair of double-strand breaks in the replicating DNA of HeLa cells

The induction and closure of double-strand breaks produced by X rays were measured in the replicating DNA of HeLa S3 cells using the techniques of neutral (pH 7.2) filter elution and pulsed-field agarose gel electrophoresis. In whole cell DNA the apparent yield of double-strand breaks in pulse-labeled DNA was approximately half that observed in bulk DNA as estimated by both techniques. In contrast, when nuclear DNA was reduced to sub-replicon-cluster lengths prior to irradiation, the yield of radiation-induced double-strand breaks was the same in both replicating and bulk DNA. During incubation of pulse-labeled whole cells at 37 degrees C, the sensitivity of pulse-labeled DNA to strand break induction approached that observed in bulk DNA with a half-time of approximately 105 min. The results indicate that double-strand breaks are produced at a similar frequency per DNA mass in both replicating and bulk DNA. The structure of replicating DNA obscures length reduction in whole cell DNA when estimated by either filter elution or gel electrophoresis. Closure of double-strand breaks proceeded at a similar rate in both replicating and bulk DNA.

Nuclear protein redistribution in heat-shocked cells

An increase was observed in the total protein mass of nuclei isolated from Chinese hamster ovary cells heated at 45 degrees C or 45.5 degrees C. An increase in the fractional recovery of DNA polymerase alpha and beta, and of DNA topoisomerase activity coincided with this increase in the protein mass of nuclei from heated cells. Nuclear protein mass which was soluble in 2.0 M NaCl decreased 0.5 fold, while DNA-associated and nuclear matrix-associated protein mass increased 2.2 and 3.4 fold, respectively. The results indicate that the increase in nuclear protein mass observed in nuclei from heated cells is due in part to an increased binding, or precipitation, of nuclear proteins onto the cell's DNA and nuclear matrix.

DNA-damage processing in a radiation-sensitive mouse cell line

The induction and repair of radiation-induced DNA damage was assessed in 3 mouse cell lines, including the parental L cell line, a radiation-sensitive, SL3-147 mutant cell line and the H5 revertant to radiation resistance. The yield of neither radiation-induced DNA single- nor double-strand breaks could explain the variable sensitivity of the 3 cell lines. Closure of DNA single-strand breaks proceeded at a similar rate in both the L and SL3-147 cell lines. Closure of DNA double-strand breaks however was significantly slower and less complete in the SL3-147 cell line than in either of the radiation-resistant cell lines. The results are consistent with the increased radiation sensitivity of the SL3-147 cell line resulting from a defect in their ability to repair radiation-induced DNA double-strand breaks.

Variation in radiation-induced formation of DNA double-strand breaks as a function of chromatin structure

The influence of chromatin structure on induction of DNA double-strand breaks (DSBs) by X radiation was studied in DNA from CHO cells. Whole cells, nuclei with condensed or relaxed chromatin, and deproteinized DNA in agarose plugs were irradiated and DSB formation was measured as a decrease in the length of DNA by nondenaturing, pulsed-field, agarose gel electrophoresis. The yield of DSBs in deproteinized DNA (2.3 x 10(-10) DSBs Da-1 Gy-1) was observed to be 70 times greater than the yield of DSBs (3.1 x 10(-12) DSBs Da-1 Gy-1) observed in DNA in the intact cell nucleus. Organization of DNA into the basic nucleosome repeat structure and condensation of the chromatin fiber into higher-order structure protected DNA from DSB induction by factors of 8.3 and 4.5, respectively. An additional twofold protection of DNA in fully condensed chromatin occurred in the intact cell nucleus. Since this protection did not appear to involve chromatin structure, we speculate that this additional protection may result from the association of soluble protein and nonprotein sulfhydryls with DNA in the intact cell nucleus. The results are consistent with the organization of nuclear DNA into both basic nucleosome repeat structure and higher-order chromatin structure providing significant protection against DSB induction.

Radiation-induced apoptosis in a murine T-cell hybridoma

Induction of an apoptotic cell death was studied in a mouse T-cell hybridoma. Apoptosis was induced in these cells following exposure to dexamethasone, X-radiation, 43 degrees C heat shock, A254 light, and hydrogen peroxide. In 5-Gy-exposed cells, a radiation-induced G2 phase cell cycle progression block was maximum by 8 h. The cells began to escape this progression block by 10 h. Nuclear DNA fragmentation and uptake of the vital dye trypan blue began at 12 and 14 h, respectively, and were complete by 28 h. X-radiation-induced cell death was diminished when cells were irradiated in the presence of dimethyl sulfoxide, indicating that cell death was induced by oxidative cell damage. Substitution of nuclear DNA with bromodeoxyuridine enhanced death in cells exposed to either X-radiation or A310 light, indicating that apoptosis could be induced by DNA damage. The results are consistent with radiation-induced apoptosis being stimulated by oxidative DNA damage. DNA damage stimulates a long-lived signal which controls the expression of apoptosis. Apoptosis is expressed in the G1 phase of the cell cycle subsequent to the cell irradiation.

Topoisomerase II activity in the replicating DNA of irradiated hamster cells

The activity of DNA topoisomerase II in the replicating DNA of irradiated Chinese hamster ovary cells was estimated by determining protein-linked DNA double-strand breaks generated in the presence of the DNA intercalative drug 4'-(9-acridinylamino) methanesulfon-m-anisidide. In the presence of this drug, DNA double-strand breaks were produced at the same rate, and with the same overall frequency, in both the bulk and the newly synthesized DNA of control cells and cells irradiated with 10 Gy. The results indicate that DNA topoisomerase II is fully active in the replicating DNA of irradiated cells and is distributed at a frequency similar to that in parental DNA.

Topoisomerase II activity in a DNA double-strand break repair deficient Chinese hamster ovary cell line

Topoisomerase II activity was measured in wild-type, Chinese hamster ovary K1 cells, and in the DNA double-strand break repair deficient xrs-6 cell line. Total topoisomerase II activity in a high salt, nuclear extract was found to be the same in both cell lines, as measured by decatenation of kinetoplast DNA networks and catenation of plasmid pBR322 DNA. While at low drug concentrations m-AMSA-induced enzyme cutting of nuclear DNA was 25% less in xrs-6 cells, the frequency of DNA breaks at high concentrations of the drug, and thus the frequency of the topoisomerase II enzyme, was the same in both cell lines. Despite the presence of equivalent enzyme levels in both cell lines, the xrs-6 cell line was 3 times more sensitive to drug-induced cytotoxicity. These results may be due to the fact that, as with X-radiation-induced DNA damage, xrs-6 cells are deficient in the capacity to rejoin topoisomerase II-induced DNA double-strand breaks.

Detection of ionizing radiation-induced DNA double-strand breaks by filter elution is affected by nuclear chromatin structure

Chinese hamster ovary cells were irradiated with 250 kVp X rays and analyzed for the presence of DNA double-strand breaks using either polycarbonate filter elution or pulsed-field agarose gel electrophoresis at neutral pH. Reduction in DNA length detected by filter elution was produced as a nonlinear function of increasing radiation dose, with a quasi-threshold at low total dose, and as a first-order function of increasing radiation dose as detected by gel electrophoresis. The quasi-threshold observed with filter elution was eliminated when nuclei were isolated from irradiated cells and their chromatin relaxed in a buffer containing low-molarity monovalent cation prior to analysis by filter elution. The results suggest either that the chemical structure of the DNA double-strand breaks produced by low-LET radiation necessitates a DNA relaxation step before they can be detected accurately by filter elution, or that at low total radiation dose a DNA complex forms on the polycarbonate filter.

Inhibition of replicon cluster ligation into chromosomal DNA at elevated temperatures

The rate-limiting enzymatic step for DNA replication in HeLa cells incubated at 43.5 degrees C was the ligation of clusters of replicons into the cell's genome. At 43.5 degrees C the reciprocal slope for inhibition of DNA chain (replicon) initiation, or of the ligation of replicon clusters into the genome, was 18 or 7 min, respectively. The failure of replicon clusters to be ligated into chromosomal DNA was not a consequence of the failure of histone proteins to be deposited onto replicating DNA, or of chromatin replicated at 43.5 degrees C to be organized into fully condensed chromatin. In addition it was not due to the failure of fully active topoisomerase II to be deposited at a normal frequency along replicating chromatin DNA. The failure of replicon clusters to be ligated into the genome resulted in the persistence of single, but not double, DNA strand breaks in the cell's genome 24 hours after cell heating.

Measurement of radiation-induced DNA damage using gel electrophoresis or neutral filter elution shows an increased frequency of DNA strand breaks after exposure to pH 9.6

The filter elution technique using nondenaturing conditions is widely used to assay DNA double-strand break (DSB) induction and repair. It has been reported that in the measurement of strand breaks higher rates of elution and of initial rejoining are obtained at pH 9.6 compared to pH 7.2. In the present experiments neutral elution at pH 7.2 and 9.6 were compared in the assay of damage to DNA induced by X rays, 125I decay, and restriction enzyme digestion, in an effort to explain this discrepancy and to determine whether the higher rate of elution observed at pH 9.6 corresponds to a greater number of DSBs. X-ray damage to cellular DNA resulted in significantly different elution profiles at the two pH values. In contrast the elution profiles of the DSB induced by intragenomic 125I decays or restriction endonuclease were independent of the pH of the elution buffer. When gamma-irradiated SV40 DNA was exposed to pH 7.2 or 9.6 elution buffer prior to analysis by gel electrophoresis, a significantly greater number of DNA DSBs were detected in the DNA exposed to pH 9.6. We conclude that X and gamma radiation produce lesions (pH 9.6-labile lesions), in proportion to dose, that have the potential of becoming measurable DSBs following incubation under the mildly alkaline condition of pH 9.6. The data suggest that these lesions may result from single-hit events.

Repair of DNA single- and double-strand breaks in proliferating and quiescent murine tumor cells

We evaluated the relationship between the repair of DNA single- and double-strand breaks and cellular radiosensitivity in proliferating vs. quiescent cells of the mouse mammary tumor lines 66 and 67 in vitro, using the technique of filter elution at pH 12.2, pH 7.2 and pH 9.6. In these lines, quiescent (Q; unfed plateau-phase) cells are more radiosensitive than are proliferating (P) cells. At doses of 4-6 Gy, both 66 and 67 Q cells repair single-strand breaks (ssb) with kinetics similar to those of P cells. However, repair of ssb was slightly retarded in Q cells at a higher dose (10 Gy) than at the lower doses. In contrast, repair of ssb in P cells was dose-independent, at least for doses up to 10 Gy. The rate of repair of DNA double-strand breaks (dsb), measured at pH 7.2, was dose-independent in P and Q cells of both lines. The repair kinetics were biphasic, with an initial half-time less than 15 min, and the early phase was similar in all cell groups. The half-time for repair in the slow phase ranged from about 2 to greater than 20 h. The fraction of damage repaired by the slow phase was relatively high in all cell groups (40-70 per cent). In line 66, P cells repaired a higher percentage of dsb by 2 h postirradiation than did Q cells. The opposite was observed in line 67: Q cells repaired more dsb in 2 h than did P cells. The survival of 66 St4 cells (Q cultures which have been refed with complete medium and incubated 4 h) was significantly greater than that of 66 Q; nevertheless St4 cells repaired both ssb and dsb at rates similar to those of Q cells. Therefore, survival does not necessarily correlate with the rates of either ssb or dsb repair among these cell lines in different growth states.

Topoisomerase activity in irradiated mammalian cells

The role of topoisomerase enzymes in the response of HeLa S3 cells to ionizing radiation was investigated. Exposure of cells to 100 Gy of X-radiation had no detectable effect either on the total cellular topoisomerase activity as measured by the relaxation of supercoiled plasmid DNA by cell sonicates or on the total cellular topoisomerase II activity as measured by plasmid DNA catenation. Total topoisomerase II activity remained constant for up to 90 min after cell irradiation. The effect of 2 drugs (caffeine and novobiocin) which inhibit topoisomerase II activity on the HeLa cell response to radiation was determined. Both drugs were found to inhibit topoisomerase II in vitro and to inhibit the recovery of nucleoid sedimentation in irradiated cells in vivo to the same extent. Topoisomerase II was inhibited by 50% by exposure to 10 mM caffeine and 0.79 mM novobiocin. At low concentrations neither drug affected the induction frequency, nor the rejoining rate, of DNA double-strand breaks. Caffeine (5 mM) inhibited the short-term recovery of cells from radiation while novobiocin (0.79 mM) had no detectable effect on the capacity of cells to recover from radiation exposure. The results indicate that topoisomerase II is not required for DNA double-strand break rejoining though it could be required for the recovery of DNA coiling in the irradiated cell. If topoisomerase II is involved at all in cell recovery from irradiation, this role does not apparently involve an ATP-dependent enzyme activity.

Cell cycle effect on the induction of DNA double-strand breaks by X rays

Filter elution was used to compare X-ray-induced DNA single- and double-strand breaks in proliferating (P) and quiescent (Q) cells of the 66 and 67 mouse mammary tumor lines. There was no difference either between cell type or between growth states in the amount of single-strand breaks as defined by elution at pH 12.2. In contrast, Q cells appeared to sustain a much larger amount of double-strand break damage per Gray than P cells, when the damage was measured by elution at either pH 7.2 or pH 9.6. Experiments which combined centrifugal elutriation with pH 7.2 elution demonstrated that G1-P cells were similar to Q (greater than or equal to 95% G1) cells in the induction of elution-detectable double-strand breaks, while the S-phase enriched fractions sustained less damage than G1-P, Q, or asynchronous P populations. Studies in which P populations were pulse labeled with [14C]thymidine confirmed this finding. Mathematical analysis of the elution kinetics of irradiated P, Q, and S-phase cells supports a model in which the complex elution profiles observed for P cells could be explained as the sum of the one-component exponential elution profiles of G1- and S-phase subpopulations. Also, the correlation between damage measured by pH 7.2 elution and cell survival was tested by examining the dose response for stimulated 66 cells (St4), which like Q cells are greater than or equal to 95% in G1 but are more resistant to X-ray-induced cytotoxicity than are the 66 Q cells. However, the induction of double-strand breaks in St4 cells was identical to that in Q cells. Thus we conclude that there is not necessarily a correlation between the amount of elution-detectable X-ray-induced double-strand breaks and cell survival.

Hyperthermia blocks DNA processing at the nuclear matrix

The capacity of control and heated HeLa cells to process newly polymerized DNA at the nuclear matrix was measured. DNA which had been pulse-labeled with [3H]thymidine was enriched by a factor of up to 6 at the cell's nuclear matrix. During continuous exposure to [3H]thymidine at 37 degrees C this enrichment for pulse-labeled DNA was reversed with a half-time of 7 min. We interpret this processing of newly replicated DNA to be a distribution of newly polymerized DNA throughout replicon-sized nuclear DNA domains. Both processing of newly polymerized DNA at the nuclear matrix and ligation of replicon clusters into the interphase cell chromosome were halted by incubation of cells at temperatures at or above 43 degrees C. When HeLa cells were pulse-labeled during a 30-min incubation at 45 degrees C and replaced at 37 degrees C, the enrichment for 3H-labeled DNA at the nuclear matrix was reversed with an initial half-time of 4 h. The results indicate that exposure of cells to hyperthermic temperatures blocks ongoing nascent DNA processing at the nuclear matrix and results in a retardation of DNA processing in preheated cells replaced at 37 degrees C.

Effect of topoisomerase II inhibitors on hyperthermic cytotoxicity

Exposure of HeLa or Chinese hamster ovary cells to drugs (novobiocin, nalidixic acid, or oxolinic acid) which inhibit the nuclear enzyme topoisomerase II resulted in a sensitization of both cell lines to hyperthermic heating at 41 and 45 degrees C. Exposure to 0.5 mg/ml novobiocin decreased the reciprocal slope (T0) of the survival curve of HeLa cells heated at 41 and 45 degrees C by a factor of 7.5 and 2.4, respectively. Exposure to 0.5 mg/ml novobiocin decreased the T0 of the survival curve of Chinese hamster ovary cells heated at 41 and 45 degrees C by a factor of 9.8 and 1.8, respectively. Exposure of HeLa cells to 0.5 mg/ml novobiocin delayed thermotolerance development for 1.5 h and depressed by a factor of 27 the survival of cells heated at 45 degrees C once thermotolerance had developed. Coincident with the sensitization to heat-induced cytotoxicity, an enhancement of a heat-induced increase in the total protein mass co-isolating with the nuclei or nuclear matrices from heated cells was observed. A log-linear correlation was found between the reduction in cell survival and the relative nuclear matrix protein mass increase in cells heated at 41 or 45 degrees C in the presence or absence of these drugs. The results are consistent with the notion that exposure to these drugs disrupts the cell's capacity to regulate nuclear structure and composition, and thus enhances heat-induced cytotoxicity.

The effect of chromatin decondensation on DNA damage and repair

The effects of chromatin compaction on X-radiation-induced cell killing and the induction and repair of DNA damage were studied in Chinese hamster ovary cells deprived of isoleucine for 24 h (Ile- cells) and compared to untreated controls. The results show that chromatin is decondensed in Ile- cells; i.e., in Ile- cells the nuclear area occupied by heterochromatin decreased 30-fold over control cells, both the rate and limit of micrococcal nuclease digestion were greater for Ile- cells, and 14.2% more propidium iodide was intercalated into the Ile- cell chromatin. The X-ray-induced cytotoxicity did not change in Ile- cells versus the control cells (D0 = 0.99 Gy) nor did the X-ray-induced DNA damage. However, the repair of DNA damage produced by 10 Gy proceeded with different kinetics in Ile- cells when compared to the controls. The initial rate of DNA damage repair was slower in Ile- cells by a factor of 2 compared to controls (the time required to rejoin 50% of the lesions was 6 versus 3 min, respectively). However, after 2 h of repair no DNA damage was detected in either group. Therefore, we conclude that this decondensation of chromatin, per se, does not directly modify the induction or ultimate repair of DNA damage by X radiation or cell clonogenicity and thus does not appear to be a primary factor in cell survival.

Apurinic site induction in the DNA of cells heated at hyperthermic temperatures

The induction of DNA damage in cells heated at hyperthermic (43-48 degrees C) temperatures was determined by alkaline filter elution and alkaline sucrose gradient-sedimentation analysis of cell DNA denatured at pH 13.0. A class of DNA lesion which converted to strand breaks during denaturation of DNA at pH 13.0 was produced randomly throughout the cell DNA at temperatures as low as 43 degrees C. Induction of this lesion occurred with a T0 of 90 and 10 min at 45 and 48 degrees C, respectively. We estimate that these pH 13.0-detectable DNA lesions are produced in the cell DNA with a frequency of approximately 75 and 660 per min of heating at 45 and 48 degrees C, respectively. Since the lesions were quantitatively converted to DNA strand breaks at pH 13.0 with a half-time of 30 min, or less, we suggest that these pH 13.0-detectable DNA lesions are heat-induced, abasic DNA sites. The induction of these lesions does not appear to be directly involved in the initial heat-induced inhibition of DNA synthesis. The presence of these lesions cannot be excluded as an explanation for the long-term inhibition of replicon initiated in heated cells.

Induction of DNA strand breaks in transcriptionally active DNA sequences of mouse cells by low doses of ionizing radiation

The efficiency of DNA single-strand break induction was measured in transcriptionally active DNA, transcriptionally inert satellite DNA, and bulk DNA sequences of mouse L929 cells using the alkaline filter elution assay. The cells were exposed to increasing doses of X-radiation up to 1000 rad. DNA which either eluted from or was retained on polycarbonate filters during the assays was collected onto nitrocellulose filters and hybridized against radiolabeled poly(A+)RNA (to probe transcribing DNA sequences) or mouse satellite DNA. The increasing rate and extent of elution of bulk DNA or specific DNA sequences after increasing radiation doses was taken as a measure of the increased frequency of radiation-induced DNA strand breaks. The results indicate that a significant fraction of transcriptionally active DNA contains endogenous strand breaks. With increasing dose, the efficiency of radiation-induced DNA strand breakage in bulk, transcriptionally active and satellite DNA sequences was observed to be the same when the sum of all eluted DNA was considered. However, the early eluting fractions contained DNA which was enriched in active sequences. Since DNA elutes as a function of size, the early fractions contain smaller DNA than later fractions. Therefore, our results indicate that the fraction of active sequences which elutes early resides on smaller fragments on the average than the later eluting DNA, and that even low doses of radiation preferentially cause breaks in regions of DNA containing active sequences.

Alterations in the nuclear matrix protein mass correlate with heat-induced inhibition of DNA single-strand-break repair

The total protein mass co-isolating with the nuclear matrix or nucleoid from Chinese hamster ovary (CHO) cells was observed to increase in heated cells as a function of increasing exposure temperature between 43 degrees C and 45 degrees C or of exposure time at any temperature. The sedimentation distance of the CHO cell nucleoid in sucrose gradients increased with increasing exposure time at 45 degrees C. Both these nuclear alterations correlated in a log-linear manner with heat-induced inhibition of DNA strand break repair. A two-fold threshold increase in nuclear matrix protein mass preceded any substantial inhibition of repair of DNA single-strand breaks. When preheated cells (45 degrees C for 15 min) were incubated at 37 degrees C the nuclear matrix protein mass and nucleoid sedimentation recovered with a half-time of about 5 h, while DNA single-strand-break repair recovered with a half-time of about 2 h. When preheated cells were placed at 41 degrees C (step-down heating; SDH) a further increase was observed in the nuclear matrix protein mass and the half-time of DNA strand break repair, while nucleoid sedimentation recovered toward control values. These results implicate alterations in the protein mass of the nuclear matrix in heat-induced inhibition of repair of DNA single-strand breaks.

Inhibition of repair of radiation-induced DNA damage by thermal shock in Chinese hamster ovary cells

The effect of exposure to elevated temperatures (41-45 degrees C) on the repair of radiation-induced DNA strand breaks was measured in monolayer cultured Chinese hamster ovary (CHO) cells. Prior exposure of cells to temperatures between 43 and 45 degrees C resulted in significant decreases in the rate of repair of DNA damage. Exposure to 45 degrees C for 15 min slowed the rate of DNA repair to 0.17 of the control repair rate. The To for inactivation of DNA repair was observed to be 34, 13 and 6 min at 43, 44 and 45 degrees C, respectively. Stepdown-heating (45 degrees C for 15 min followed by repair at 41 degrees C) resulted in greater inhibition of DNA repair (0.11 of the control rate) than was observed after acute heating alone. Repair at 41 degrees C was observed to proceed in unheated cells at a faster rate than at 37 degrees C. An Arrhenius analysis of the inactivation kinetics of DNA repair between 43 and 45 degrees C indicated an activation energy of 140 kcal mol-1 of protein for the inhibition of DNA repair. In general, the results were inconsistent with either a retardation of the DNA repair rate or an increase in unrepaired DNA lesions being responsible for heat-induced radiosensitization.

A calmodulin antagonist has no effect on the repair of X-ray-induced damage in a murine mammary carcinoma cell line

The effects of the calmodulin antagonist W13 were determined on potentially lethal damage repair, sublethal damage repair, and X-ray-induced DNA damage repair following X irradiation of 67 murine mammary carcinoma cells in the proliferative and quiescent states. Studies with W13 (20 micrograms/ml) on proliferating cells showed that the cells rounded up within 2 h but stayed attached to the dishes and there was a slight transient G2 block by 6 h. Also, the proportion of S-phase cells at 12 h was reduced to 65% of control with the concurrent [3H]thymidine incorporation reduced to 62% of control. There was no detectable effect from this pharmacological dose of W13 either on PLDR in proliferating cells at 400 and 800 rad or on quiescent cells at 200 and 400 rad. Likewise, there was no measurable effect on SLDR in either proliferating or quiescent cells at equally split doses of 800 and 600 rad, respectively. In addition, for control vs W13-treated proliferating cells, no difference was detected either in the induction of DNA damage by X irradiation or in the initial rate of repair (T 1/2 approximately equal to 7 min), as measured by the alkaline filter elution assay. In contrast to uv and bleomycin-induced damage, these data suggest that calmodulin may have no major role in either the molecular or cellular recovery from X-ray-induced damage in mammalian cells.

Heat shock (45 degrees C) results in an increase of nuclear matrix protein mass in HeLa cells

The nuclear matrix from HeLa cells heated at 45 degrees C was isolated to determine the effect of thermal shock on its composition and structure. The matrix from unheated cells contained about 10 per cent of total cell protein and was observed to be spherical particle with a diameter ranging from 3 to 5 microns with the major constituent polypeptides having molecular weights of 45, 47, 55, 57, 59 and 65 kilodaltons. The nuclear-matrix protein mass increased linearly with increasing exposure time at 45 degrees C with no observable change in its size or shape. The additional proteins were observed in general to have molecular weights greater than 45 kilodaltons, with marked increases in polypeptides of 28.5, 38.5, 60, 66, 75, 81, 88, 100 and 115 kilodaltons. An exponential relationship was observed between heat-induced cytotoxicity and the nuclear matrix protein mass increase. A 15 per cent increase in matrix protein mass was sustained prior to the onset of cytotoxicity, while a 35 per cent increase in matrix protein content was associated with a 63 per cent probability of cell killing. The results indicate that redistribution of cell protein or alterations in the mass or structure of the nuclear matrix may be involved in heat-induced cytotoxicity.

DNA damage production in CHO cells at elevated temperatures

Induction of DNA lesions in the nucleus of Chinese hamster ovary (CHO) cells was observed at hyperthermic temperatures using the alkaline filter elution and the alkaline sucrose gradient sedimentation methods. These lesions were observed principally at temperatures greater than 45 degrees C with an activation energy of 140 kcal/mole. On alkaline sucrose gradients the cell genome was reduced to a 140 S or 2 X 10(8) dalton subunit of DNA independent of increasing exposure time at temperatures above 45 degrees C. The large thermal activation energy and the limited DNA size reduction suggest the possible involvement of thermal denaturation of a nuclear polypeptide in the production of these nuclear lesions.

Fluorescence studies of Hoechst 33342 with supercoiled and relaxed plasmid pBR322 DNA

The fluorescence properties of Hoechst 33342 (HO 33342) were examined with plasmid pBR322 in the supercoiled (Form I) or relaxed covalently closed circular (Form Io) conformation in order to determine whether qualitative or quantitative differences in fluorescence properties might provide an assay for topological states of DNA. It was found that HO 33342 exhibited a 30% greater fluorescence intensity with Form I pBR322, independent of the dye or DNA concentration. As the dye to DNA ratio was increased, a red shift of approximately 8 nm was observed for HO 33342 complexed with Form I or Form Io. The red shift in fluorescence emission occurred at higher HO 33342 concentrations with Form I vs. Form Io DNA; however, when Form I and Form Io were mixed in various proportions, neither the fluorescent intensity differences nor the HO 33342 concentration at which the wavelength shift occurred could be used to quantitate the relative proportions of topological states present. These results suggest that although the fluorescence properties of HO 33342 complexed with Form I DNA are different than those of HO 33342 complexed with Form Io DNA, the fluorescence assay is not sufficiently sensitive to quantitatively discriminate among a mixture of DNA in various topological states.

DNA damage repair in quiescent murine mammary carcinoma cells in culture

Murine mammary carcinoma cells (line 67) were grown in unfed cultures for up to 9 days. In cultures (day 2-3) in which cells were proliferatively active and in day 3-5 (transition) cells, a large fraction of nuclear DNA was retained on polycarbonate filters when assayed by the alkaline filter elution technique. In contrast, the fraction of DNA retained on filters was significantly reduced for nonproliferating (Q, quiescent) cells from unfed 7-9 day cultures. The increase in endogenous DNA breaks followed both the decrease in proliferative state and clonogenicity in these cells. When day 7 Q cells were refed these endogenous DNA breaks were removed with a half-time of about 2.5 h. When the cells were exposed to X-irradiation and the integrity of their nuclear DNA measured by the alkaline filter elution assay, as much as a 2-fold greater frequency of radiation-induced DNA breaks was produced in Q versus P cells. DNA breaks were also removed from irradiated Q cells at a rate which was 0.23 that observed in P cells. We suggest that the depressed capacity for DNA damage removal in Q cells is responsible for their greater radiosensitivity, and the impaired DNA damage repair is probably due to a reduced level of energy sources in these unfed Q cell cultures.

Inhomogeneity of the nucleus to 125IUdR cytotoxicity

Synchronized suspension cultures of Chinese hamster ovary (CHO) cells were used to determine the lethal effects produced by the decay of 125I incorporated into different subfractions of the nuclear genome. Such a shift in nuclear incorporation pattern was achieved by using the drug aphidicolin, which inhibits 95% of all nuclear DNA synthesis, is nontoxic to cells in a colony-forming assay, and does not modify the radiation response of CHO cells to X irradiation. In addition to shifting incorporation of 125I to only 5% of the nuclear genome, both nuclease digestions to characterize the molecular location of 125I and electron microscope autoradiography show an inhomogeneous distribution of sites of 125I incorporation in the presence of 5 micrograms/ml aphidicolin. These data in combination with survival curves of CHO cells labeled with 125I-iododeoxyuridine (125IUdR) either with or without aphidicolin showed a dramatic change in the survival response (DO: 30 decays/cell and 96 decays/cell, respectively). It is concluded, therefore, that the nucleus is not a homogeneous target for radiation-induced cell death because when subfractions of the nuclear genome are labeled, radically different levels in cell survival are obtained.

The sedimentation coefficient and buoyant density of nucleosomes from replicating chromatin in heated cells

The sedimentation coefficient and buoyant density of mononucleosomes from the replicating chromatin of heated (45 degrees) and unheated HeLa cells were determined. It was observed that both physical parameters were the same (S = 10.8 and p = 1.165 g/cm3) for nucleosome particles from replicating and mature chromatin in heated and unbeated cells. The size of DNA in the nascent and mature nucleosome from heated or unheated cells was observed to be 145 base pairs of double-stranded DNA. A significant fraction of nucleosomal DNA from heated cells was observed at subnucleosomal sizes, principally at 125 base pairs of DNA. It is concluded that 45 degrees thermal shock does not alter appreciably the subunit structure of chromatin at the replication fork.

Histone protein and DNA synthesis in HeLa cells after thermal shock

Exposure of suspension-cultured HeLa cells to a 45 degrees thermal shock resulted in cell inactivation and inhibition of both protein and DNA synthesis. DNA synthesis was inhibited in a biphasic manner with a more sensitive (Do = 7 min) and a less sensitive (Do = 20 min) phase. The less sensitive process was demonstrated to be DNA chain elongation. Transport of thymidine into intracellular pools was significantly less sensitive to thermal shock (Do in excess of 200 min). When HeLa cells were heated at 45 degrees for 15 min there was an 80% inhibition of incorporation of precursors into both DNA and protein with little effect on precursor transport into cellular pools. While the rate of synthesis of whole cell and histone protein (H2a, H2b, H3, and H4) and DNA chain elongation recovered by 6 h after cell heating, total precursor incorporation into DNA was only 0.4 of control levels. The long-term depression of the DNA synthetic rate could not be explained by a cell cycle redistribution, a depression in the total fraction of S phase cells synthesizing DNA, or by a depression in the rate of DNA chain elongation. We conclude that thermal shock results in a long-term depression in the fraction of cell replicons involved in DNA replication.

Macromolecule synthesis in HeLa cells after thermal shock

The incorporation of radioactivity into HeLa cell polypeptides and DNA after exposure to 45 degrees C heating for 15 min was measured by continuous exposure to radiolabeled precursors. Both polypeptide and DNA synthesis were inhibited by thermal shock. The rate of incorporation of radiolabeled amino acids into whole cell, nuclear, or histone protein recovered to control levels by 5 to 8 hr after thermal shock. The rate of incorporation of radiolabeled thymidine into DNA did not recover to a control level within the first 8 hr after thermal shock. Thermal effects on amino acid and nucleotide precursor pools could not explain the inhibition of either protein or DNA synthesis. Since histone protein synthesis recovers prior to DNA synthesis, we conclude that the inhibition of histone protein synthesis after thermal shock is not responsible for the depression in synthesis of cellular DNA.

The effects of hyperthermia on DNA replication in HeLa cells

The extent of heat-induced inhibition of DNA replication in HeLa cells was assayed at temperatures between 43 and 48 degrees C. During hyperthermic exposure replicon initiation, as well as elongation of replicons into larger replicative fragment sizes, was rapidly inhibited. Elongation of nascent DNA into replicons continued at a normal rate for up to 45 min at 45 degrees C. Heated cells, replaced at 37 degrees C, elongated nascent DNA at a reduced rate and elongation was incomplete for up to 36 hr. Nascent DNA, not fully elongated 24 hr after hyperthermic exposure, was observed in replicative fragment sizes as small as replicons. The extent of heat-induced inhibition of DNA elongation increased with increasing time-temperature exposure with an activation energy of 122 kcal/mole of DNA. When pulsed cells were incubated at 37 degrees C for various times prior to heating, the extent of heat-induced inhibition of DNA elongation decreased with a half-time of 20-25 min, suggesting that the heat-sensitive structure is associated with replicative fragments having sizes less than 140-150S.

DNA degradation in chinese hamster ovary cells after exposure to hyperthermia

Chinese hamster ovary cells grown in suspension showed a progressive reduction in the size of their nuclear DNA to 50 to 60S fragments after hyperthermia (43-48 degrees). This DNA degradation was not a homogeneous response but was observed only in cells incapable of attaching to a substratum after acute heating. The DNA degradation was associated with the inability of cells to exclude the vital stain, trypan blue. The degradation process appeared to be a result of nucleolytic enzyme digestion which accompanies cell necrosis. A similar phenomenon was observed in heated monolayer cells but only after significantly greater time-temperature exposures. Our results show that cellular subpopulations can be separated after hyperthermia and that these subpopulations are biochemically distinct and characterized by different viability.

Heat protection by glycerol in vitro

Heating of either Chinese hamster ovary or HeLa cells in medium containing glycerol protected against thermal killing. Above glycerol concentrations of 100 mM, protection of Chinese hamster ovary cells increased in a concentration-dependent manner. Exposure to glycerol only, before or after heating at 45 degrees, did not protect against cell killing. Glycerol protection against thermal damage was also expressed at the subcellular level. The fractional increase in the protein:DNA ratio for nuclei from heated HeLa cells (15 min, 48 degrees) was 1.6 with heating in 1 M glycerol, compared to 2.0 for medium controls. Both glycerol (1 M) and heat-induced thermotolerance (4 hr, 41.5 degrees) partially reversed the sensitizing effects of pH 6.4 and stepdown heating at 41.5 degrees. The partial deprivation of nutrients achieved by incubating cells in Hanks' balanced salt solution-sensitized Chinese hamster ovary cells against 45 degrees hyperthermia. Glycerol reversed this sensitization but only when nutrient deprivation was short term (75 min). With a long-term, 8.5-hr exposure to glycerol in Hanks' balanced salt solution, cells were significantly more sensitive to heat killing at 41.5 degrees than were cells heated for an equal period in Hanks' balanced salt solution alone. The similarities in the characteristics of glycerol protection and heat-induced thermotolerance suggest a common mechanistic basis for the two phenomena, although the ability of glycerol to act as a sensitizer in nutrient-deprived cells is not understood.