Alkaline step elution analysis of gamma-ray induced DNA strand breaks and repair in diploid yeast

Gamma-ray induction of DNA strand breaks and their repair was analysed in the diploid yeast strain D7 (Saccharomyces cerevisiae) by means of the alkaline step elution technique. A dose-dependent increase of DNA strand breakage was observed in the dose range 25-2000 Gy corresponding to 100 and 0.01 per cent survival. When, after exposure to gamma-irradiation, the cells were incubated for 2 h in liquid growth medium, the elution profiles reached the pattern of unirradiated controls, thus indicating the restoration of cellular DNA due to repair. The alkaline step elution analysis is found to be a useful and reproducible technique for studying the induction of DNA strand breaks and repair in yeast. In comparison with other current methods, such as alkaline sucrose gradients and DNA unwinding, this method appears to be more rapid, versatile and easier to handle.     

DNA damage in mouse and rat liver by caprolactam and benzoin, evaluated with three different methods

Benzoin and caprolactam were examined for their capability of inducing alkaline DNA fragmentation in mouse and rat liver DNA after treatment in vivo. Three different methods were used. With the alkaline elution technique we measured an effect presumably related to the conformation of the DNA coil. With a viscometric and a fluorometric unwinding method we measured an effect presumably related to the number of unwinding points in DNA. For both compounds only the alkaline elution technique was clearly positive. The results suggest that both caprolactam and benzoin can induce an important change in the conformation of the DNA coil without inducing true breaks in DNA.     

Molecular dosimetry of DNA damage caused by alkylation. II. The induction and repair of different classes of single-strand breaks in cultured mammalian cells treated with ethylating agents

Cultured Chinese hamster ovary cells were treated with ethylating agents. DNA lesions giving rise to single-strand breaks (SSB) or alkali-labile sites were measured by elution through membrane filters at pH 12.0 and pH 12.6, and by centrifugation in alkaline sucrose gradients after 1 h and 21 h lysis in alkali. Two agents with different tendencies to ethylate preferentially either at N or O atoms were compared, namely N-ethyl-N'-nitro-N-nitrosoguanidine (ENNG) and diethyl sulphate (DES). The compounds differed greatly in their potency to induce lesions, but the ratios of SSB, measured with different methods after a treatment for 30 min, did not differ significantly. This suggested that the spectrum of lesions induced by the two compounds is very similar. However, when both agents were studied with alkaline elution at pH 12.0 after a short treatment time (5 min) only ENNG was found to induce rapidly-repairable SSB. Most of these were rejoined already within 5 min after treatment. These results suggest that rapidly-repairable lesions occurring in DNA after treatment of mammalian cells with ethylating agents are due mainly to alkylation at O-atoms.     

Comparison of DNA Strand Break Induction in CHO Cells Measured by Alkaline Elution and by Fluorometric Analysis of DNA Unwinding (FADU)

DNA damage in X-irradiated CHO cells was measured by alkaline filter elution and compared to fluorometric analysis of DNA unwinding (FADU). The FADU method proved to be as sensitive as the alkaline filter elution technique in detecting X-ray induced DNA breaks. Strand break induction was also measured after treatment with four radical generating chemicals (hydrogen peroxide, bleomycin, mitomycin C and methyl viologen) using the FADU technique.     

Comparison of DNA Strand Break Induction in CHO Cells Measured by Alkaline Elution and by Fluorometric Analysis of DNA Unwinding (FADU)

DNA damage in X-irradiated CHO cells was measured by alkaline filter elution and compared to fluorometric analysis of DNA unwinding (FADU). The FADU method proved to be as sensitive as the alkaline filter elution technique in detecting X-ray induced DNA breaks. Strand break induction was also measured after treatment with four radical generating chemicals (hydrogen peroxide, bleomycin, mitomycin C and methyl viologen) using the FADU technique.     

Differentiation of apurinic/apyrimidinic sites and single-strand breaks in DNA by formamide- and alkaline-sucrose gradient sedimentation

The excision repair of DNA damaged by physical or chemical agents may produce either apurinic/apyrimidinic (AP) sites or single-strand breaks (SSB) in the DNA. Alkaline-sucrose gradient sedimentation and alkaline elution, techniques generally used for the study of DNA repair which depend upon high pH to denature the DNA, cannot differentiate between these possibilities. A simple method for the quantitative measurement of SSB in DNA which leaves any AP sites intact is presented. This method relies upon the separation by size of the fragments resulting from the denaturation of the DNA under neutral conditions by sedimentation through gradients of sucrose in formamide. By combining the use of both formamide- and alkaline-sucrose sedimentation methods, we can quantify both AP sites and SSB in DNA.     

DNA conformation of Chinese hamster V79 cells and sensitivity to ionizing radiation

Chinese hamster V79 cells grown for 20 h in suspension culture form small clusters of cells (spheroids) which are more resistant to killing by ionizing radiation than V79 cells grown as monolayers. This resistance appears to be due to the greater capacity of cells grown in contact to repair radiation damage. Attempts to relate this "contact effect" to differences in DNA susceptibility or DNA repair capacity have provided conflicting results. Two techniques, alkaline sucrose gradient sedimentation and alkaline elution, show no difference in the amounts of radiation-induced DNA single-strand breakage or its repair between suspension or monolayer cells. However, using the alkali-unwinding assay, the rate of DNA unwinding is much slower for suspension cells than for monolayer cells. Interestingly, a decrease in salt concentration or in pH of the unwinding solution eliminates these differences in DNA unwinding kinetics. A fourth assay, sedimentation of nucleoids on neutral sucrose gradients, also shows a significant decrease in radiation damage produced in suspension compared to monolayer cultures. It is believed that this assay measures differences in DNA conformation (supercoiling) as well as differences in DNA strand breakage. We conclude from these four assays that the same number of DNA strand breaks/Gy is produced in monolayer and spheroid cells. However, changes in DNA conformation or packaging occur when cells are grown as spheroids, and these changes are responsible for reducing DNA damage by ionizing radiation.     

Alzheimer's disease fibroblasts have normal repair of N-methyl-N'-nitro-N-nitrosoguanidine-induced DNA damage determined by the alkaline elution technique

Cultured fibroblast strains from two normal persons and from two patients with the neurodegeneration of Alzheimer's disease were exposed to the alkylating chemical N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). Immediately after exposure and also after a 24-h repair incubation period the single-strand breaks in the cells' DNA were quantified by the alkaline elution technique. In contrast to a report by others using alkaline elution, MNNG, and these same strains, we found no evidence of deficient repair of MNNG-induced DNA damage in the Alzheimer's disease cells. The putative DNA repair defect in Alzheimer's disease should be investigated by methods other than the alkaline elution technique which measures only a small fraction of the damage induced by an alkylating chemical such as MNNG.     

Repair of Alkylation Damage: Stability of Methyl Groups in Bacillus subtilis Treated with Methyl Methanesulfonate

Bacillus subtilis was not inactivated and was able to replicate even though approximately 3 x 10(4) methyl groups added by methyl methanesulfonate (MMS) were bound to the deoxyribonucleic acid (DNA) of each organism. No significant loss of methyl groups from the DNA occurred for several generations upon incubation of methylated wild-type or MMS-sensitive cells. Single-strand breaks were not observed in the DNA from cells treated at this low MMS dose. Higher doses of MMS resulted in significant killing of both wild-type and MMS-sensitive strains, and the DNA extracted from such treated cells sedimented more slowly than control DNA through alkaline sucrose gradients, indicating the presence of breaks or apurinic sites (or both). These breaks were repaired upon incubation of wild-type but not of MMS-sensitive strains. Repair of damage induced by alkylating agents is probably the repair of breaks which occur as a consequence of high levels of alkylation.     

Quantitation of chemically induced DNA strand breaks in human cells via an alkaline unwinding assay

DNA strand breaks induced in human CCRF-CEM cells by electrophilic chemicals (carcinogens/mutagens) can be readily quantitated via a facile alkaline unwinding assay. This procedure estimates the number of chemically induced DNA strand breaks on the basis of the percentage DNA converted from double-stranded to single-stranded form during an exposure to the alkaline unwinding conditions. The assay is based on the assumption that each strand break serves as a strand unwinding point during the alkaline denaturation. The extent of strand separation can be standardized with respect to the initial level of induced strand breaks by the use of X-rays, which produce known levels of DNA strand breaks per rad in mammalian cells. Subsequent to the alkaline exposure, the single- and double-stranded DNA were separated by use of thermostated hydroxylapatite columns (60 degrees C), and the DNA was quantitated via a fluorescence assay (Hoechst 33258 compound). A correlation was shown between mammalian DNA strand-breaking potential (as measured in this procedure) and the propensity of these chemicals to revert Salmonella typhimurium TA100.     

DNA strand breaks induced by low-energy heavy ions

The DNA unwinding method was used to estimate DNA breakage in Chinese hamster cells exposed to heavy ions with LET in the range of 750-5000 keV/micron. Comparison of the primary induced unwinding rate per dose unit for ions with various track diameters but similar LET showed a pronounced influence on the track diameter. Low-energy ions, producing thin tracks with diameters (penumbra) in the submicrometer region, were almost two orders of magnitude less efficient than more energetic ions producing tracks with diameters of several micrometers and about three orders of magnitude less efficient than X-rays. For the thin tracks, clustering of breaks was indicated by comparison of the DNA unwinding rates in two different alkaline solutions. The results indicate that the unwinding rate cannot be used as a good measurement for DNA breaks in this case. The residual unwinding remaining after 4 h of repair at 37 degrees C correlated well with the ability of the various ions to produce cell-killing.     

Application of alkaline unwinding assay for detection of mutagen-induced DNA strand breaks

The frequency of single-strand breaks in parental DNA and gaps in nascent DNA in various cells exposed to methyl methanesulfonate (MMS) or methylnitrosourea (MNU) was investigated by alkaline unwinding assay using two types of alkaline lysis conditions, 22°C lysis versus 0°C lysis. The DNA damage induced by MMS and MNU is considered to be characteristic of lesions produced in DNA by alkylating agents. The aim of our research project was to adjust this method to be able to detect the greatest number of DNA lesions induced by alkylating agents in parental DNA of different mammalian cells. In our experiments we used human cell lines EUE, GM637 and XP12, Chinese hamster V79 cells, and Syrian hamster embryo cells. The higher level of strand interruptions was detected under conditions of lysis of cells at 22°C. Probably the level of strand interruptions found after the lysis of cells at 22°C correlates with the increased number of disrupted alkali-labile sites of DNA. It is remarkable that the different lysis conditions did not influence the number of gaps detected in nascent DNA of alkylated cells. Comparing induction of breaks and gaps in radiolabelled strands of parental and daughter DNA under different lysis conditions, we succeeded in defining the optimum conditions for detection of alkali-labile sites of parental DNA.     

DNA breakage detection-fish (DBD-FISH): effect of unwinding time

DBD-FISH is a new procedure that allows detection and quantification of DNA breakage in situ within specific DNA target sites. Cells embedded in an agarose matrix on a slide are treated in an alkaline unwinding solution to transform DNA breaks into single-stranded DNA (ssDNA). After removal of proteins, DNA probes are hybridized and detected. DNA breaks increase the ssDNA and relax supercoiling of DNA loops, so more probe hybridizes, thereby increasing the surface area and fluorescence intensity of the FISH signal. The probe selects the chromatin area to be analysed.In order to restrict the extension of unwound ssDNA to a region closer to the origin of the DNA break, human leukocytes were processed for DBD-FISH with a whole genome probe, after a 10 Gy dose of X-rays, for various unwinding times: 5, 2 min and 30s. Two cell populations were detected after 30s, but not with the 5 or 2 min unwinding times. One cell group had small to medium haloes corresponding to the relaxation of DNA supercoiling after DAPI staining, and strong DBD-FISH labelling of induced DNA breaks, whereas the other cell group showed big haloes of DNA loop unfolding and an absence of DBD-FISH labelling. The latter group was similar to cells processed by DBD-FISH without the unwinding step. Thus, they should correspond to cells unaffected by the alkaline unwinding solution, possibly because very brief unwinding times do not allow the diffusion of the alkali into the cells deep within the gel, thus biasing the results. Taking this into account, 2 min seems to be the minimum unwinding time required for an accurate detection of a signal by DBD-FISH.     

Alkaline elution of rat testicular DNA: Detection of DNA strand breaks after in vivo treatment with chemical mutagens

The alkaline elution technique was used to measure DNA strand breaks in rat testes after intraperitoneal injection of several chemicals known to cause heritable mutations in rodents. Methyl methanesulfonate (MMS), ethyl methanesulfonate, methylnitrosourea, and ethylnitrosourea all produced single strand breaks in rat testicular DNA. For both of these pairs of homologous alkylating agents the relative potency was methyl analog ethyl analog. Strand breaks produced by MMS appeared rapidly (within 2 h) in rat testicular DNA and were partially repaired within 24 h. Studies with low doses of MMS indicate that the assay has the sensitivity to detect DNA strand breaks in the testis after a dose of only 5 mg/kg. Variability in DNA elution profiles for individual control animals and for individual animals given identical doses of MMS was small. In contrast to the results with known mutagens, intraperitoneal injection of nonmutagens such as dimethyl sulfoxide, phenol, and Triton X-15, did not produce strand breaks in testicular DNA.These data indicate that this assay detects DNA strand breaks in the rat testis. The results of several heritable mutagens and nonmutagens are qualitatively predictive of mutagenic activity in the testis.     

Similar degree of methyl methanesulphonate-induced DNA damage in two clones ofTradescantia differing in mutagenic sensitivity to alkylating agents

In two clones ofTradescantia (4430 and 02) differing in the sensitivity to the mutagenic action of alkylating agents, equimolar doses of [¹⁴C] methyl methanesulphonate (MMS) elicited a similar degree of protein, RNA and DNA alkylation and a similar amount of DNA-7-methylguanine and DNA-3-methyladenine in cells of inflorescence. Moreover, in the same clones and tissues the same doses of nonlabelled MMS produced a similar amount of DNA single strand breaks and/or alkali labile sites as measured in alkaline sucrose gradients. None of the DNA lesions followed is therefore decisive for explanation of the different mutagenic sensitivity ofTradescantia clones.     

The regulation of DNA repair in mammalian cells. I. The repair of DNA radiation damages in Swiss 3T6 mouse cells under the action of the epidermal growth factor and insulin

Methods of centrifugation in alkaline sucrose gradients as well as alkaline and neutral elution on filters were used to show a significant reduction in the rate of both single- and double-strand DNA breaks in the quiescent mouse Swiss 3T6 cell culture as compared to the proliferating one. The low efficiency of repair of single-strand DNA breaks in quiescent cells may result from a nearly complete absence of the fast repair of DNA lesions during the first minutes of postradiation incubation. The epidermal growth factor in combination with insulin (no other serum component present) leads to a recovery of the repair process. The stimulating effect of mitogens on the repair of both single- and double-strand DNA breaks allows to suggest that similar factors may be responsible for these recovery processes.     

A hydroxylapatite batch assay for quantitation of cellular DNA damage.

A batch elution procedure is described for quantitative measurement of DNA damage. The technique is based on alkaline unwinding of cellular DNA and separation of singlestranded from duplex forms by step elution from hydroxylapatite with phosphate formamide. The method is rapid, permits large numbers of samples to be handled simultaneously, and consistently yields recoveries of >95% of total chromatographed DNA. Because as many as 1 × 10⁷ cells per batch may be analyzed, quantitation of the eluted DNA by nonradioactive methods is feasible. The method is standardized with respect to the unwinding constant β, the alkaline DNA unwinding unit Mng, and the DNA-damaging efficiency of ionizing irradiation.     

Strand breakage in DNA by silicic acid

The alkaline unwinding assay has been used to demonstrate the formation of single-strand breaks in DNA on treatment with silicic acid. Double-stranded DNA, containing no single-strand breaks, when incubated with increasing concentrations of silicic acid, showed the formation of an increasing number of strand breaks per molecule. Experiments on reduction of silicic acid-treated DNA with NaBH4 suggested the possibility of creation of apurinic or apyrimidinic sites. The significance of silicic acid interaction with cellular DNA during asbestos exposure is discussed.     

Studies on DNA damage: Discordant responses of rate of DNA disentanglement (viscosimetrically evaluated) and alkaline elution rate,obtained for several compounds

Alkaline elution is a well-known method for detecting DNA damage. Recently we have developed a viscosimetric method that is even more sensitive than alkaline elution. Here we report that the two methods, although apparently both revealing alkaline DNA fragmentation, can give dramatically different results for a significant series of compounds. We suspect that alkaline elution might reveal not only DNA fragmentation but also the extent of disentanglement of chromatin structure, whereas this DNA disentanglement rate, when evaluated viscosimetrically, is more strictly correlated with the initiation of DNA unwinding.     

DNA repair in a fanconi's anemia fibroblast cell strain

DNA repair and colony survival were measured in fibroblasts from a patient with Fanconi's anemia, HG 261, and from normal human donors after exposure of these cells to the cross-linking agent mitomycin C, X-rays or ultraviolet light. Survival was similar in HG 261 and normal cells after X-ray or ultraviolet radiation, but was reduced in the Fanconi's anemia cells after treatment with mitomycin C. The level of DNA cross-linking, as measured by the method of alkaline elution, was the same in both cell strains after exposure to various doses of mitomycin C. With incubation after drug treatment, a gradual decrease in the amount of cross-linking was observed; the rate of this apparent repair of cross-link damage was the same in both normal and HG 261 cells. The rejoining of DNA single strand breaks after X-irradiation and the production of excision breaks after ultraviolet radiation were also normal in HG 261 cells as determined by alkaline elution.