Fixation of potentially lethal radiation damage by post-irradiation exposure of Chinese hamster cells to 0.5 M or 1.5 M NaCl solutions.

The effect of 0.05 M and 1.5 M NaCl treatments on CHO cells during and after irradiation has been examined. Treatment with either hypotonic or hypertonic salt solutions during and after irradiation resulted in the fixation of radiation damage which would otherwise not be expressed. The half time for fixation was 4 to 5 min, and the increased expression of the potentially lethal damage by anisotonic solutions was mainly characterized by large decreases in the shoulder of the survival curve, as well as by decreases in DO. Fixation of radiation damage at 37 degrees C occurred to a much greater extent for the hypertonic treatment than for the hypotonic treatment and was greater at 37 degrees C than at 20 degrees C. Although both the hypotonic and hypertonic treatments during and after irradiation reduced or eliminated the repair of sublethal and potentially lethal damage, treatment during irradiation only, radiosensitized the cells when the treatment was hypotonic, and radioprotected the cells when the treatment was hypertonic. These observations are discussed in relation to salt treatments and different temperatures altering competition between repair and fixation of potentially lethal lesions, the number of which depends on the particular salt treatment at the time of irradiation.     

Ataxia-telangiectasia homo- and heterozygous cells show a normal repair and fixation response to anisotonic NaCl treatment after irradiation

The effect of anisotonic NaCl treatment on fixation and repair of radiation-induced potentially lethal damage (PLD) was tested in normal human cells and in three homozygous ataxia-telangiectasia (A-T) and two heterozygous A-T cell strains. Fixation of radiation-induced PLD occurred in all cell strains exposed to 0.05, 0.5, or 1.5 mole/liter NaCl solutions immediately after irradiation. This effect was observed in both plateau-phase and exponentially growing normal and A-T cells. When an incubation period at 37 degrees C was introduced between irradiation and the subsequent anisotonic treatment, recovery was observed in both normal and A-T cells strains. These data show that A-T cells are as proficient as normal cells in repairing PLD that is sensitive to anisotonic NaCl treatment. It is proposed that two PLD repair systems may exist, one that is expressed after irradiation in proliferatively arrested cells and another that occurs in plateau-phase as well as exponentially growing cells, and is expressed by the postirradiation treatments described here and by Raaphorst and Azzam (Radiat. Res. 86, 52-66 (1981].     

Fixation and repair by anisotonic treatment of radiation damage leading to oncogenic transformation

Mouse embryo (C3H 10T1/2) cells were exposed to anisotonic NaCl solutions or combined treatments of radiation and anisotonic solutions. Anisotonic treatment with 0.05 or 0.5 mol/l solutions did not cause transformation and only prolonged exposure at 1.5 mol/l caused significant increases in transformation. When cells were irradiated in the presence of 0.05 mol/l NaCl, increased transformation occurred than when cells were irradiated in medium. Thus, anisotonic treatment after irradiation resulted in fixation of potentially lethal and transformed radiation damage. Fixation of potentially transformed damage was greater for cells irradiated in the presence of 0.05 mol/l NaCl than for cells irradiated in medium. When the NaCl treatment after irradiation was delayed by incubation at 37 degrees C, recovery of potentially lethal and potentially transformed damage was observed.     

Repair and fixation of potentially lethal damage (PLD) as demonstrated by delayed plating or incubation with araA in contact inhibited refed plateau-phase C3H mouse embryo 10 T1/2 cells grown in the presence of BrdUrd

Summary OH mouse 10 T_1/2 cells showing strong inhibition of growth at confluency were grown under daily refeeding in the presence of BrdUrd (from 0 to 1 µM) and exposed to-rays either while exponentially growing or in the plateau phase. An increase in radiosensitivity was observed in both growth conditions mainly reflected by a reduction in Dq. Greater radiosensitization was observed in exponentially growing than in plateau-phase cells, and 3–4 times higher BrdUrd concentrations were required in plateau-phase cells for similar potentiation in killing. This effect could not be entirely attributed to a reduction in BrdUrd incorporation since measurements with³H-BrdUrd showed reductions in incorporation between only 17–47% in plateau-phase cells. The rate of repair of potentially lethal damage (PLD) as demonstrated by delayed plating was not affected by the incorporation of BrdUrd, but the amount of repair (measured as the relative increase in cell survival) was higher for BrdUrd-containing cells. Post-irradiation treatment of cells in the plateau-phase (no BrdUrd) with 9--d-arabinofuranosyladenine (araA) caused fixation of radiation-induced PLD. AraA treatment of cells grown in the presence of various amounts of BrdUrd also caused fixation of PLD, but resulted in survival levels similar to those observed with cells growing in BrdUrd-free medium. This result indicates that BrdUrd mediated radiosensitization cannot be observed when cells are prevented from repairing PLD by postirradiation incubation with araA. Based on these findings we propose that the mechanism of radiosensitization by BrdUrd incorporation might be, by increasing probability of fixation, mediated by the postirradiation progression of cells through the cycle, of a sector of PLD also sensitive to post-irradiation treatment with araA. For this sector of PLD the term -PLD has been proposed.This investigation was partly supported by PHS grants CA33951, CA39938 and CA42026 awarded by NCI, DHHS     

Relationship between DNA damage,DNA repair,metabolic state and cell lethality

Summary Induction of unrepairable DNA damage, accumulation of misrepaired DNA damage, and generation of imbalances in competing biochemical and/or metabolic processes have been proposed to explain the relationship between radiation-induced DNA damage and cell lethality. Theoretically, the temperature dependence of the critical DNA repair process(es) should be 1) either independent of or identical to the temperature dependence of cell killing if the first two hypotheses are correct, and 2) different if the third hypothesis is correct. To test this, exponentially growing rat 9L brain tumor cells were left at 37°C or equilibrated for 3–14 h at 20°C before irradiation. Cells were irradiated and allowed to repair at either 20°C or 37°C. Alternatively, the cells were irradiated at one of these temperatures and immediately shifted to the other temperature for repair. DNA damage was assessed by the alkaline elution technique; cell kill was assessed by a clonogenic assay. 9L cells maintained at 20°C or 37°C sustained the same amount of DNA damage as measured by alkaline elution. DNA repair instantaneously assumed the rate characteristic of the postirradiation temperature. For 9L cells equilibrated, irradiated, and repaired at 20°C, the half-time of the fast phase of the DNA repair decreased by a factor of 2 and the half-time of the slow phase decreased by a factor of 5 over that measured in cells incubated, irradiated and repaired at 37°C. Although the rate of DNA repair decreased substantially at 20°C, the survival of 9L cells that were equilibrated and irradiated at 20°C was greater (p <10^–4) than those incubated and irradiated at 37°C, when assayed by an immediate plating protocol. In addition, the survival of 9L cells equilibrated and irradiated at 20°C and then shifted to 37°C immediately after irradiation was greater (p <10^–2) than that obtained with any other delayed plating protocol. Thus, the temperature dependence of the DNA repair processes measured by alkaline elution was different from the temperature dependence of cell killing measured either by an immediate or delayed plating protocol. These data support the hypothesis that many irradiated 9L tumor cells die because of imbalances in sets of competing biochemical and/or metabolic processes.Presented at the 81st Annual Meeting of the American Association for Cancer Research, May 23–26, 1990 in Washington, DC     

Analysis of the excision repair of nondimer DNA damage induced by solar ultraviolet radiation in ICR 2A frog cells

The excision repair of solar uv-induced nondimer DNA damage was examined in ICR 2A frog cells through the use of the bromodeoxyuridine (BrdUrd) photolysis assay. A relatively pure population of nondimer DNA photoproducts was induced by irradiation of ICR 2A cells with the Mylar-filtered solar ultraviolet (uv) wavelengths produced by a fluorescent sunlamp followed by exposure to photoreactivating light (PRL) which removes most of the small yield of pyrimidine dimers induced by this treatment. Cultures of cells were also exposed to 254 nm uv, which induces primarily dimers, and 60Co gamma rays. Through use of a modification of the BrdUrd photolysis assay possessing enhanced sensitivity, it was found that the solar uv-induced nondimer DNA damage was repaired by a short patch repair mechanism in which less than approximately 20 nucleotides are inserted into a repaired region. Similar results were also obtained for gamma-irradiated cells. In contrast, excision repair of 254-nm-induced dimers was accomplished by a long-patch process in which an average of about 180 nucleotides are inserted into the repaired sites.     

The effect of bromodeoxyuridine and ultraviolet light on 9L rat brain tumor cells

Incorporation of the thymidine analog bromodeoxyuridine (BrdUrd) into DNA increases the sensitivity of a cell to uv light. We have examined the effect of uv light on cell killing and alkaline elution profiles in 9L rat brain tumor cells pretreated with BrdUrd. Combination treatment with BrdUrd and uv irradiation produced a dose enhancement ratio of 3.8 at the 10% survival level compared with uv-radiated control cells; cell killing depended on both the time of treatment and the concentration of BrdUrd used for incubation. Sequential treatment caused single-strand breaks and DNA-protein crosslinks in the portion of DNA containing BrdUrd; uv irradiation alone caused very few strand breaks and no DNA-protein crosslinks. Because of the presence of both lesions in cells treated with BrdUrd and uv light, it was possible to calculate crosslinking factors without using a charging X-ray dose to induce strand breaks, the method commonly used with crosslinking drugs. Results of repair studies suggested that single-strand breaks are repaired more rapidly than are DNA-protein crosslinks.     

The effect of hypothermic treatment on the repair or expression of X-ray damage measured in split dose experiments on L5178Y-S cells

Summary The nature of the post-irradiation lesions and processes leading to cellular reproductive death or survival were investigated in mouse lymphoblastic leukemia L5178Y-S (LY-S) cells. Post-(x-)irradiation incubation at 25° C protects LY-S cells against the fixation of biologically expressed damage which takes place at 37° C. An optimal condition for the repair of damage, assayed in split-dose experiments as split-dose recovery (SDR), is 1 h at 37° C followed by 4 h holding at 25° C prior to the second half of a split dose, or 5 h holding at 25° C without a 37° C incubation during the interval between doses. Longer incubations at 37° C resulted in progressively decreased survivals. Postirradiation inhibition of DNA synthesis at 37° C was observed only during the first 30 min; thereafter,³H-dThdR incorporation washigher than in unirradiated controls. Theexcess synthesis effect was removed by shifting irradiated cells to 25° C holding. The inhibition observed at 25° C was reversed by shifting to 37° C. Thus the degree of postirradiation DNA synthesis is inversely related to SDR. DNA filter elution shows complete strand break repair by 20 min at 37° C, and by 3 h at 25° C; DNA double-strand break (DSB) repair plateaus at 80% (37° C) and 60% (25° C) after 90 min. An inverse correlation was found between total strand break repair rate, as assayed by filter elution methods, and cell survival. This work was supported by a grant from The Mathers Charitable Foundation.A preliminary report of this work was presented at the 35th Annual Meeting of the Radiation Research Society, Atlanta, GA 1987, USA     

An examination of the repair saturation hypothesis for describing shouldered survival curves

The hypothesis that after irradiation a competition exists between fixation of radiation damage and its repair and that this competition determines cell survival was to be tested. Postirradiation temperature of holding was employed as a means of modulating rate of damage repair, and the postirradiation rates of repair of DNA strand breaks (both single and double) were monitored using elution assays. At temperatures below 37 degrees C following irradiation the rates of rejoining were decreased markedly, although rejoining of single-strand breaks was seen even at 10 degrees C and rejoining of double-strand breaks still occurred at 16 degrees C. However, 3 h incubation of cells at these lowered temperatures had no observable effect on cell survival parameters. It is concluded that either damage fixation and damage repair have the same dependence on temperature, or simple measurements of rejoining of breaks are insufficient to detect the details of the competition between repair and fixation (some measure of fidelity of repair is needed).     

Radiation-induced potentially lethal damage: DNA lesions susceptible to fixation

The various postirradiation incubation conditions reported to uncover potentially lethal damage (PLD) induced by ionizing radiation are outlined and critically discussed. The process of damage fixation is the most characteristic determinant in distinguishing between PLD and other forms of damage (lethal or non-lethal). The results compiled indicate the induction of two forms of PLD (termed alpha- and beta-PLD). Evidence is presented that repair and fixation of alpha-PLD may underlie the variation in radiosensitivity observed through the cycle. Beta-PLD appears to be sensitive only to postirradiation treatment in anisotonic sale solutions. Results obtained at the DNA and chromosome level, under conditions allowing repair or causing fixation of PLD, are reviewed and combined together to devise a qualitative model that outlines a possible sequence of events from damage fixation at the DNA level, to damage fixation at the chromosome level and, ultimately, to cell death. It is suggested that damage uncovered at the cellular level as potentially lethal, comprises DNA dsb (single, pairs or groups) and that fixation is mediated by forces transmitted to the double helix through alteration (local or general) in chromatin conformation. Changes in chromatin conformation are caused either as a result of the cell's progression through the cycle or in response to a postirradiation treatment. The fixation process leads to the induction of chromosome aberrations. The validity of the concept of PLD in in vivo systems is shown, and the possible importance of PLD repair in radiation therapy is reviewed. The concept of PLD is compared to the concept of sublethal damage, and the possibility that similar molecular lesions underlie both types of damage is discussed.     

DNA-protein cross-linking by ultraviolet radiation in normal human and xeroderma pigmentosum fibroblasts.

DNA-protein cross-linking by ultraviolet radiation was measured in human fibroblasts by an adaptation of the method of DNA alkaline elution. To measure cross-linking, a controlled frequency of DNA single-strand breaks was introduced by exposing the cells to a low dose of X-ray at 0 degrees C prior to analysis by alkaline elution. The effect of prior exposure of the cells to ultraviolet radiation was to reduce the rate and/or extent of DNA elution from X-irradiated cells. This effect was attributed to DNA-protein cross-linking, since the effect was reversed by treatment of the cell lysates with proteinase-K. Cross-linking in normal human fibroblasts occurred immediately after ultraviolet irradiation, prior to the appearance of DNA single-strand breaks due to excision repair. Upon incubation of normal cells after exposure, to ultraviolet radiation, the cross-linking was partially repaired. In xeroderma pigmentosum cells, cross-links appeared as in normal cells, but there was no repair. Instead, the extent of cross-linking appeared to increase upon incubation after ultraviolet irradiation.     

In vivo repair of UV-irradiation damage of single stranded DNA phage phi-X 174

Summary When E. coli C cells, infected with UV irradiated X 174, were allowed to grow in liquid tris-glucose medium at 37° C with aeration, the UV damage of the single stranded (ss) DNA could be repaired to some extent. Such repair was not possible if the irradiated phage were plated immediately on E. coli C in the usual double layer agar method, or if the infected complexes were initially exposed to 0.02 M KCN for 15 min before they were allowed to grow in tris-glucose medium as before. Our results indicate that in order to be repaired, ss DNA containing UV damage must be able to convert itself to a closed circular double stranded replicative form (RF) within the host cells escaping prior scission. The whole process of repair was found to be dependent on protein synthesis in the infected complexes.     

Interaction function gamma(x) for Chinese hamster cells treated with hypertonic phosphate-buffered saline after irradiation

The repair of potentially lethal damage (PLD) in stationary-phase V79 Chinese hamster cells, which was expressible by a postirradiation treatment with hypertonic (0.5 M NaCl) phosphate-buffered saline (PBS), was analyzed within the framework of the theory of dual radiation action. The interaction function gamma(x) was estimated for cells permitted to repair PLD for various intervals of time. The experimental data indicated that 50-60% of the lethal lesions produced at the time of irradiation were repaired in 120 min. The repair of PLD was implicitly involved in the probability of the interaction of sublesions. That is, g(x,trep) was defined as the probability that two sublesions separated by distance x interact to produce a lethal lesion which will not be repaired until the fixation by treatment with hypertonic PBS at time trep after irradiation. It is concluded that the time dependence of the repair of PLD is not independent of the interaction distance x. Three conclusions are drawn: (1) The repair of a lesion produced by a long distance interaction is not detectable by postirradiation treatment with hypertonic PBS. (2) A lesion produced by a short distance interaction is rapidly repaired in about 20 min. (3) A lesion produced by the interaction of sublesions separated by a distance of about 100 nm is repaired slowly.     

Evidence for the induction of two types of potentially lethal damage after exposure of plateau phase Chinese hamster V79 cells toγ-rays

Summary The fixation of-rays induced potentially damage (PLD) caused after treatment either with-araA or in medium made hypertonic by the addition of sodium chloride was studied in plateau phase chinese hamster V79 cells. Treatment with-araA was found to affect a sector of PLD, the fixation of which specifically reduced the shoulder width of the survival curve. The effect was maximized when cell survival reached levels corresponding to an exponential line, with a slope similar to the final slope of the survival curve of untreated cells. This effect was achieved by a four hour treatment with-araA at concentrations above 150µM. Longer treatment times or incubation at higher-araA concentrations did not significantly enhance the effect. Treatment in hypertonic medium, on the other hand, enhanced cell killing in a concentration dependent (NaCl-concentration) way and the survival reached values much lower than those corresponding to an exponential line. No indication for a plateau in the effect, indicating complete fixation of the sector of PLD that reacts sensitively to this treatment, was obtained. Both the slope and the shoulder width of the survival curve were affected, the slope first being increased after short treatment times (up to 10 min), followed by a decrease in the shoulder width after longer treatment times (longer than 10 min). Lesions fixed after treatment with-araA were repaired within four hours, whereas the repair of lesions fixed after treatment in hypertonic medium (460 mM NaCl, 30 min) appeared to be biphasic, with a fast component (completed in about one hour) correlated with a decrease in the slope and a slow component (completed in four hours) correlated with restoration of the shoulder width. Based on these results, we suggest that two types of PLD may be induced in plateau phase V79 cells after exposure to-rays. One, the repair of which is completed within about one hour and which affects the slope of the survival curve, and a second, the repair of which takes place in a few hours and which specifically affects the survival curve shoulder width. The terms-PLD and-PLD are suggested for the first and second component, respectively.Comparison of the repair rates of-PLD as measured with the help of-araA and of sublethal damage as measured in split-dose experiments indicated that these two cellular repair processes have very similar kinetics when measured under the same experimental conditions. Furthermore, the rate was identical at which the shoulder of the survival curve reappeared (shoulder width was the only parameter of the survival curve affected in this type of experiment) in the time interval between either a conditioning dose of-rays and subsequent graded doses or between irradiation and treatment with-araA. Based on these results it is suggested that-PLD and sublethal damage may have a common molecular base.This work was supported by PHS-grants number CA 33951 and CA 39938 awarded by NCI, DHHS     

Hyperthermia in a differentiating murine erythroleukaemia cell line: II. Effect of heat on haem induction by radiation

Friend erythroleukaemia cells (FELC) were induced to a haem-producing state by X-rays. The percentage of haem positive cells was maximum for doses between 10 and 15 Gy. Heat treatment at 42.0 degrees C or 45.0 degrees C during or after irradiation inhibited haem induction whereas heating before irradiation enhanced it. Incubation at 37 degrees C between heating and irradiation resulted in a decline in induction levels, indicating repair of heat damage that interacts with X-ray damage. Incubation at 37 degrees C between irradiation and heating did not result in changed haem induction levels, indicating a lack of repair of radiation damage that could interact with subsequent damage produced by heating.     

Defective repair of gamma-ray induced DNA damage in xeroderma pigmentosum cells.

We used the bromouracil-photolysis technique to estimate the sizes of the repaired regions in normal human and xeroderma pigmentosum (XP) cells irradiated by gamma-rays aerobically or anoxically. After 1 1/2 hours of incubation, single-strand breaks were repaired and the repaired regions were small--one to two BrUra residues--for cells irradiated aerobically or anoxically. After a 20-hour incubation, the repaired region in normal cells showed a component mimicking U.V.-repair. There were large patches (approximately 30 BrUra residues) in the approximate ratios of one per six chain breaks for aerobic irradiation and one per three chain breaks for anoxic irradiation. XP cells, however, only showed large patches at 20 hours if they had been irradiated aerobically. We could not detect such regions in XP cells irradiated anoxically. These results indicate (1) that some part of ionizing damage mimics excision of U.V. damage in that the repair patches are large and the repair takes an appreciable time; (2) the types of such damage depend on whether the irradiation is done aerobically or anoxically; and (3) XP cells are defective in repairing a component of anoxic damage.     

Independent forms of potentially lethal damage fixed in plateau-phase Chinese hamster cells by postirradiation treatment in hypertonic salt solution or araA

Plateau-phase Chinese V79 hamster cells were sequentially treated after exposure to gamma rays in medium made hypertonic by the addition of sodium chloride (370 mM) and with various concentrations of 9-beta-D-arabinofuranosyladenine (araA) to study their combined effect on fixation of potentially lethal damage (PLD). A 10-min treatment in hypertonic medium fixed an extensive amount of PLD and caused a decrease in D0 from 1.8 to 1.2 Gy without significantly affecting Dq. Subsequent treatment with araA caused further fixation of PLD but resulted in a specific, concentration-dependent reduction in Dq from 4.9 to 1.6 Gy after a 4-h exposure to 150 microM araA. A 30-min treatment in hypertonic medium reduced not only Do (from 1.8 to 1.0 Gy) but also Dq (from 4.9 to 2.7 Gy). Subsequent treatment with araA in this case affected only the residual shoulder, reducing it to 1.6 Gy after a 4-h treatment with 100 microM araA, a value similar to that obtained after treatment with araA of cells exposed to salt for only 10 min. When the repair of PLD fixed by a 10-min treatment with salt was measured by delaying its postirradiation application in the presence of various amounts of araA, a small decrease in the repair rate was observed but no significant effect on the relative increase in survival. Qualitatively similar results were obtained for repair of PLD sensitive to araA after a 10-min treatment in hypertonic medium. These results suggest the radiation induction of forms of PLD with different sensitivity to fixation by postirradiation treatments. araA is proposed to fix a form of PLD termed alpha-PLD, the repair of which takes place within 4-6 h and which causes the formation of the shoulder in the survival curve of cells plated immediately after irradiation. Short treatments in hypertonic medium (less than 10 min) are proposed to fix a form of PLD termed beta-PLD, the repair of which takes place within 1 h and leads to restoration of the slope to values equal to those obtained in the survival curve of cells plated immediately after irradiation. However, longer treatments in hypertonic medium also affect Dq and thus also alpha-PLD. Repair of beta-PLD was not significantly affected by araA and repair of alpha-PLD was not significantly affected by short hypertonic treatment, thus indicating the independence of the two forms of PLD.(ABSTRACT TRUNCATED AT 400 WORDS)     

DNA-PKcs Inhibition Sensitizes Cancer Cells to Carbon-Ion Irradiation via Telomere Capping Disruption

Heavy-ion irradiation induces a higher frequency of DNA double strand breaks (DSBs) which must be properly repaired. Critical shortening of telomeres can trigger DNA damage responses such as DSBs. Telomeres are very sensitive to oxidative stress such as ionizing radiation. The DNA-dependent protein kinase catalytic subunit (DNA-PKcs) is the central component in the non-homologous end joining (NHEJ) repair complex and participates in telomere maintenance. Therefore, it is expected to enhance the cell killing effect of heavy-ion irradiation via DNA-PKcs inhibition. To test this hypothesis, cellular radiosensitivity was measured by the clonal genetic assay. DNA damage repair was relatively quantified by long PCR. Apoptosis was quantified by flow-cytometric analysis of annexin V/PI double staining, and senescence was analyzed by galactosidase activity. Telomere length was semi-quantified by real-time PCR. P53 and p21 expression was determined by western blotting. Our data demonstrated that MCF-7 and HeLa cells with DNA-PKcs inhibition were more susceptible to carbon-ion irradiation than Those without DNA-PKcs inhibition. Even though NHEJ was inhibited by the DNA-PKcs specific inhibitor, NU7026, most DNA damage induced by carbon-ion irradiation was repaired within 24 hours after irradiation in both cell lines. However, potential lethal damage repair (PLDR) could not restore cellular inactivation in DNA-PKcs inhibited cells. MCF-7 cells showed extensive senescence and accelerated telomere length reduction, while HeLa cells underwent significant apoptosis after irradiation with NU7026 incubation. In addition, both cell lines with shorter telomere were more susceptible to carbon-ion radiation. Our current data suggested that DNA-PKcs inhibition could enhance cellular sensitivity to carbon-ion radiation via disturbing its functional role in telomere end protection. The combination of DNA-PKcs inhibition and carbon-ion irradiation may be an efficient method of heavy-ion therapy.     

Relationship between DNA repair and cell recovery: Importance of competing biochemical and metabolic processes

Summary The relationship between the inhibition of repair of radiation-induced DNA damage and the inhibition of recovery from radiation-induced potentially lethal damage (PLD) by hypertonic treatment was compared in 9L/Ro rat brain tumor cells. Fed plateau phase cultures were-irradiated with 1500 rad and then immediately treated for 20 min with a 37° C isotonic (0.15 M) or hypertonic (0.50 M) salt solution. The kinetics of repair of radiation-induced DNA damage as assayed using alkaline filter elution were compared to those of recovery from radiation-induced PLD as assayed by colony formation. Hypertonic treatment of unirradiated cells produced neither DNA damage nor cell kill. Post-irradiation hypertonic treatment inhibited both DNA repair and PLD recovery, while post-irradiation isotonic treatment inhibited neither phenomenon. However, by 2 h after irradiation, the amount of DNA damage remaining after a 20 min hypertonic treatment was equivalent to that remaining after a 20 min isotonic treatment. In contrast, cell survival after hypertonic treatment remained 2 logs lower than after isotonic treatment even at times up to 24 h. These results suggest that the repair of radiation-induced DNA damageper se is not causally related to recovery from radiation-induced PLD. However, the data are consistent with the time of DNA repair as an important parameter in determining cell survival and, therefore, tend to support the hypothesis that imbalances in sets of competing biochemical or metabolic processes determine survival rather than the presence of a single class of unrepaired DNA lesions.     

Enzyme cytochemistry of unfixed leukocytes and bone marrow cells using polyvinyl alcohol for the diagnosis of leukemia

Summary Cytochemical methods for the demonstration of enzyme activities in blood and bone marrow cells were systematically improved by the addition of an inert polymer, polyvinyl alcohol (PVA), to the incubation medium and by using optimized reaction media. The methods investigated were tetrazolium salt methods for lactate, glucose-6-phosphate, succinate and glutamate dehydrogenase, the indoxyl-tetrazolium salt method for alkaline phosphatase, the diaminobenzidine method for peroxidase, and diazonium salt methods for chloroacetate esterase, -glucosaminidase, -glucuronidase, acid phosphatase, and dipeptidylpeptidase II and IV. PVA in the media preserved the morphology of cells very well and prevented leakage of large molecules such as enzymes from the cells. Therefore, fixation or long periods of air-drying prior to incubation leading to substantial loss of enzyme activity could be avoided. A brief period of drying (2 min at 37° C) of the cell preparations just before the incubation was sufficient for making the cells permeable. Localization of enzyme activities was very precise and precipitation of the final reaction product was confined to sites which are known to contain the enzyme under study (granules, mitochondria, lysosomes). These advantages advocate the use of PVA in haematological enzyme cytochemistry and especially for diagnosis of leukemia.