The formation and repair of single-strand breaks in DNA of cultured mammalian cells treated with UV-light, methylating agents or 4-nitroquinoline-1-oxide.

The technique of sedimentation in alkaline sucrose was used to examine the formation and repair of single-strand (SS) breaks in cultured mammalian cells that were treated with methyl methanesulfonate (MMS), methyl nitrosourea (MNUA), 4-nitroquinoline-1-oxide (4NQO) or UV-light. The SS breaks induced by MMS and 4NQO were largely repaired by HeLa cells during a 5-h post-treatment incubation. The SS breaks induced by MNUA and UV-light were not repaired by HeLa cells. L-cells were not able to repair the SS breaks induced by any of the agents, which correlates with the deficiency of these cells for repair synthesis of DNA. The following conclusions are discussed. MNUA and UV-light produce modifications in DNA which are not repaired but are translated into SS breaks in alkali. MMS produces SS breaks intracellularly but these are not derived from a simple depurination of methylated purines. 4NQO produces a modification in DNA which is translated into an SS break in alkali but which can be removed by an intracellular process.     

Cellular responses and repair of single-strand breaks introduced by UV damage endonuclease in mammalian cells

Although single-strand breaks (SSBs) occur frequently, the cellular responses and repair of SSB are not well understood. To address this, we established mammalian cell lines expressing Neurospora crassa UV damage endonuclease (UVDE), which introduces a SSB with a 3'-OH immediately 5' to UV-induced cyclobutane pyrimidine dimers or 6-4 photoproducts and initiates an alternative excision repair process. Xeroderma pigmentosum group A cells expressing UVDE show UV resistance of almost the wild-type level. In these cells SSBs are produced upon UV irradiation and then efficiently repaired. The repair patch size is about seven nucleotides, and repair synthesis is decreased to 30% by aphidicolin, suggesting the involvement of a DNA polymerase delta/epsilon-dependent long-patch repair. Immediately after UV irradiation, cellular proteins are poly(ADP-ribosyl)ated. The UV resistance of the cells is decreased in the presence of 3-aminobenzamide, an inhibitor of poly(ADP-ribose) polymerase. Expression of UVDE in XRCC1-defective EM9, a Chinese hamster ovary cell line, greatly sensitizes the host cells to UV, and addition of 3-aminobenzamide results in almost no further sensitization of the cells to UV. Thus, we show that XRCC1 and PARP are involved in the same pathway for the repair of SSBs.     

Differential effects of glutathione depletion and metallothionein induction on the induction of DNA single-strand breaks and cytotoxicity by tert-butyl hydroperoxide in cultured mammalian cells

Induction of DNA single-strand breaks (ssb), their resealing and cytotoxicity by tert-butyl hydroperoxide (t-BuOOH) were investigated in cultured Chinese hamster V79 cells. The effect of the depletion of cellular glutathione (GSH), iron chelation and induction of metallothionein (MT) on these parameters was studied. t-BuOOH in a concentration range of 0.02-0.5 mM induced DNA ssb in a dose-dependent fashion. Strand breakage increased as a function of time up to 1 h. Divalent iron chelator o-phenanthroline suppressed markedly the induction of DNA ssb while the trivalent iron chelator desferrioxamine had no effect. GSH-depletion increased cytotoxicity of t-BuOOH. In contrast, the depletion of GSH did not affect the efficiency of formation of DNA ssb by t-BuOOH and the rate of resealing of the DNA damage. The induction of MT did not influence the efficiency of formation of DNA ssb by t-BuOOH. In summary, while GSH depletion and MT induction affected the formation of DNA ssb and cytotoxicity differently divalent iron was required for both. Therefore, appears likely that DNA breakage and cytotoxicity by t-BuOOH are caused by independent mechanisms.     

Induction and repair of DNA single-strand breaks in EM9 mutant CHO cells treated with hydrogen peroxide

In this study we investigated the induction and rejoining of DNA single-strand breaks (SSBs) produced by H2O2 in the repair-deficient EM9 mutant Chinese hamster ovary (CHO) cell line. The effect of the poly(ADP-ribose)-transferase inhibitor 3-aminobenzamide (3-ABA) on SSB-rejoining and on cell killing was also evaluated. Results were compared with those obtained previously with the parent cell line (AA8). Cells were treated with H2O2 on ice for 1 h, after which they were either harvested or allowed to repair their damage at 37 degrees C either in the presence or absence of 3-ABA (5 mM). The cells were then assayed either for survival using a colony-forming assay or for their level of DNA SSBs using alkaline elution. EM9 cells were somewhat more sensitive than AA8 cells to the cytotoxic effects of H2O2. However, because the repair mutant showed slightly lower levels of DNA SSBs than did its parental cell line, this sensitivity could not be explained on the basis of alterations in initial damage. The rejoining of the H2O2-induced DNA SSBs followed exponential kinetics in both cell lines; however, EM9 cells rejoined these breaks at a slower rate (t1/2 of 10 min) than did AA8 cells (t1/2 of 5 min). The increased sensitivity of the EM9 cells therefore appears to correlate with a reduced ability to remove these lesions from their DNA. As previously demonstrated for the AA8 cells, 3-ABA treatment resulted in both a retardation of the removal of H2O2-induced DNA SSBs and potentiation of cytotoxicity in the EM9 cells. However, the degree of these effects were similar for both AA8 and EM9 cells. These data provide further evidence that the cytotoxic effects of low concentrations of H2O2 are mediated by damage to DNA, and suggest that the rate at which DNA SSBs are rejoined is important for cell survival.     

Inducible repair of DNA single-strand breaks in gamma-irradiated Chinese hamster cells

Preirradiation of Chinese hamster cells with low-level UV-light does not influence the efficiency of repair of gamma-radiation-induced DNA single-strand breaks. With fractionated gamma-irradiation, cycloheximide delivered during the interval between the two fractions reduces the number of DNA breaks (compared to that in cells affected by the same nonfractionated dose). The data obtained indicate the presence of an inducible component of repair of DNA single-strand breaks in gamma-irradiated Chinese hamster cells.     

Induction and repair of DNA strand breaks in cultured mammalian cells following fast neutron irradiation.

Induction and repair of DNA breaks following irradiation with NIRS cyclotron neutrons were studied in cultured mammalian cells (L5178Y) in comparison to those following gamma-rays. The yield of the total single-strand breaks, 3'OH terminals and sites susceptible to S1 endonuclease following fast neutrons was found to be approximately 50 per cent of that following gamma-irradiation. On the other hand, the yield of double-strand breaks was slightly higher after fast neutrons than after gamma-rays. The percentage of the total single-strand breaks remaining unrejoined at 3 hours after post-irradiation incubation was found to be distinctly higher after the fast neutrons than after gamma-rays. The neutron-induced damage appears to carry a higher proportion of alkali-labile lesions compared to gamma-rays. It was concluded that the increase in the yield of double-strand breaks and of unrejoinable breaks is responsible for a high r.b.e. of the cyclotron neutrons.     

Evidence for AP site formation related to DNA-oxygen alkylation in CHO cells treated with ethylating agents

DNA single-strand breaks (ssb) induced by N-ethyl-N-nitrosourea (ENU) in CHO cells are quickly resealed within 10 min after treatment. This rapid repair kinetics is not explained by the rate of base excision repair which removes the main ethyl products with a half-life in the order of hours. We have explored the potential use of methoxyamine (MX), a chemical that reacts at neutral pH with AP sites in DNA in vitro, to clarify the origin of ENU-induced ssb. The presence of 50 mM MX during cell treatment with diethyl sulfate (DES) caused selective inhibition of the repair of AP sites generated during base excision repair and inhibited alkaline cleavage at these sites. The treatment of CHO cells with ENU in the presence of MX clearly showed that the burst of ssb observed immediately after treatment was due to AP site formation. Plasmid DNA treated in vitro with ENU did not present AP endonuclease-sensitive sites; therefore, the AP sites produced in CHO cells by ENU treatment are not due to the chemical hydrolysis of a very unstable ethyl adduct but rather are intermediates of an as yet undefined enzymatic pathway. This process occurs specifically after treatment with SN1-type ethylating agents (ENU and N-ethyl-N'-nitro-N-nitrosoguanidine) suggesting an association between this phenomenon and DNA-oxygen alkylation. We suggest that these breaks are generated by a mechanism of O6-ethylguanine processing without removal of the modified base.     

Induction and subsequent repair of DNA damage by fast neutrons in cultured mammalian cells

The induction and repair of DNA damage were studied by a DNA unwinding method in mouse L5178Y cells exposed to fast neutrons. DNA lesions induced by fast neutrons were classified into three types from their repair profiles: fast-reparable breaks (T1/2 = 3-5 min), slow-reparable breaks (T1/2 = 70 min), and nonreparable breaks. The repair rates of both fast-reparable and slow-reparable breaks were almost the same as those of corresponding damage induced by low-LET radiation. Neutrons induced a smaller amount of fast-reparable damage, an almost equal amount of slow-reparable damage, and a larger amount of nonreparable damage than those induced by equal doses of gamma rays or X rays. RBEs for fast- and slow-reparable damage were 0.3 and 0.9, respectively. The RBE for nonreparable damage was dose dependent and was 1.4 at the level of 100 breaks/10(12) Da DNA. Among the three types of lesions, only the nonreparable damage levels correlated with the linear-quadratic shape of the survival curves and with the enhanced killing effectiveness of neutrons (RBE = 1.7 at D0).     

The specificity of different classes of ethylating agents toward various sites in RNA.

The alkyl products of neutral in vitro ethylation of TMV-RNA by [14C]diethyl sulfate, [14C]ethyl methanesulfonate, and [14C]ethylnitrosourea have been determined and found to differ significantly depending on the ethylating agent. Diethyl sulfate and ethyl methanesulfonate ethylate the bases of TMV-RNA in the following order: 7-ethylguanine greater than 1-ethyladenine, 3-ethylcytidine greater than 7-ethyladenine, 3-ethyladenine, O6-ethylguanosine, 3-ethylguanine. Ethyl methanesulfonate was more specific for the 7 position of guanine, and other derivatives were found in lesser amounts than with diethyl sulfate. Neither reagent caused the formation of detectable amounts (smaller than 0.26 percent) of 1-ethylguanine, 1,7-diethylguanine, N2-ethylguanine, N6-ethyladenine, N4-ethylcytidine, or 3-ethyluridine. Identified ethyl bases account for over 85% of the total radioactivity of [14C]ethyl methanesulfonate and [14C]diethyl sulfate treated TMV-RNA. Phosphate alkylation accounts for about 13 and 1%, respectively, In contrast, [14C]ethylnitrosourea-treated TMV-RNA, while reacting to a similar extent (15-70 ethyl groups/6400 nucleotides), is found to cause considerably more phosphate alkylation. Upon either U4A RNase or acid hydrolysis up to 60% of the radioactivity is found as volatile ethyl groupw in the form of [14C]ethanol, and a further 15% appears to be primarily ethyl phosphate and nucleosides with ethylated phosphate. Of the remaining radioactivity, half is found as O6-ethylguanosine, the major identified ethyl nucleoside. Other ethyl bases found in ethylnitrosourea-treated TMV-RNA are 7-ethylguanine greater than 1-ethyladenine, 3-ethyladenine, 7-ethyladenine, 3-ethylcytidine, and 3-ethylguanine. It appears that ethylnitrosourea preferentially alkylates oxygens, and that formation of phosphotriesters is by far the predominant chemical event. Since the number of ethyl groups introduced into TMV-RNA by ethylnitrosourea is similar to the number of lethal events, one may conclude that phosphate alkylation leads to loss of infectivity. None of the three ethylating agents studied are strongly mutagenic on TMV-RNA or TMV. The role of phosphate alkylation in regard to in vivo mutagenesis and oncogenesis remains to be established. At present it appears possible that the extent of this reaction may correlate better with the oncogenic effectiveness of different ethylating agents, than the extent of any base reaction. Unfractionated HeLa cell RNA is ethylated primarily in acid labile manner even by diethyl sulfate and ethyl methanesulfonate, a fact that is attributed to its high content of low molecular weight trna rich in terminal phosphates which alkylate readily.     

Comparative studies on induction and rejoining of DNA single-strand breaks by radiation and chemical carcinogen in mammalian cells in vitro

This study, using the 5–20% alkaline sucrose gradient method, indicated that single-strand breaks of DNA in cultured mammalian cells were induced as a linear function of the dose of X-ray and chemical carcinogen (4-HAQO). The rejoining of broken single-strand of DNA induced by these agents seems to consist of two processes: an initial rapid rejoining process and a late slow rejoining process. Single-strand breaks of cellular DNA induced by these two agents rejoin at nearly the same rate for each of the two processes during incubation.