Degradation and repair of rat hepatoma cell DNA following exposure to gamma rays and methylnitrosourea]

Single-strand breaks induced in DNA of ascitic hepatoma cells by gamma-rays and N-methyl-N-nitrosourea (MNU), resp., may be effectively repaired. Double-strand breaks of DNA from MNU-treated hepatoma cells are also effectively repairable in vivo. Only a small part of double-strand breaks induced by gamma-rays in DNA of these cells is repaired in the postradiation period. The combined action of gamma-rays and MNU on the hepatoma cells causes a complete inhibition of repair of DNA and its further degradation. Under these conditions, inhibition of the repair of DNA synthesis and repression of DNA polymerase I activity is observed.     

The role of N-nitrosourea-induced changes in the nucleoid structure and activity of repair enzymes in the development of drug resistance in mice with leukemia L1210

Using centrifugation of the nucleoid in a neutral sucrose gradient, the damages in the secondary structure of DNA and the activity of repair enzymes, such as DNA-polymerases alpha and beta and poly(ADP-riboso) polymerase, induced by 1-methyl-nitrosourea (MNU) and 1.3-bis (2-chloroethyl)-1-nitrosourea (BCNU) injected at maximal nonlethal single doses to mice bearing parent leukemia cells (L1210/0) and resistant to MNU and BCNU leukemia L1210 cells (L1210/MNU and L1210/BCNU), were studied. The MNU-induced production of single-strand breaks in L1210/0 and L1210/MNU cells was more conspicuous in newly replicated DNA than in those in preexisting DNA. A more fast repair of the damages in newly replicated DNA was detected in L1210/BCNU and especially in L1210/MNU leukemia cells as compared with L1210/0 cells. The data obtained suggest that there are prone errors in the repair of DNA template, since most of the single-strand breaks were revealed in the newly replicated DNA synthesized on the repaired DNA. The repair of DNA damages in L1210/BCNU and especially in L1210/MNU cells was accompanied by the activation of DNA-polymerases alpha and beta and poly(ADP-riboso)polymerase. Both DNA-polymerases--alpha and beta--were shown to be involved in repair of DNA damages induced by MNU and only DNA-polymerase beta was involved in the repair of damages induced by BCNU.     

Differential sensitivity of DNA replication and repair in permeable Escherichia coli exposed to various monofunctional methylating or ethylating agents.

Escherichia coli cells made permeable to deoxynucleoside triphosphates by brief treatment with toluene (permeablized) were used to measure the effect of the following chemical alkylating agents on either DNA replication or DNA repair synthesis: methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), N-methyl-N-nitrosourea (MNU), N-ethyl-N-nitrosourea (ENU), N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) and N-ethyl-N′-nitro-N-nitrosoguanidine (ENNG). Replication of DNA in this pseudo-in vivo system was completely inhibited 10–15 min after exposure to MMS at concentrations of 5 mM or higher or to MNU or MNNG at concentrations of 1 mM or higher. The ethyl derivatives of the alkylating agents were less inhibitory than their corresponding methyl derivatives, and inhibition of DNA replication occurred in the following order: EMS < ENNG < ENU. Maximum inhibition of DNA replication by all of the alkylating agents tested except EMS occurred at a concentration of 20 mM or lower. The extent of replication in cells exposed to EMS continued to decrease with concentrations of EMS up to 100 mM (the highest concentration tested).The experiments in which the inhibition of DNA replication by MMS, MNU, or MNNG was measured were repeated under similar assay conditions except that a density label was included and the DNA was banded in CsCl gradients. The bulk of the newly synthesized DNA from the untreated cells was found to be of the replicative (semi-conservative) type. The amount of replicative DNA decreased with increasing concentration of methylating agent in a manner similar to that observed in the incorporation experiments.Polymerase I (Pol I)-directed DNA repair synthesis induced by X-irradiation of permeablized cells was assayed under conditions that blocked the activity of DNA polymerases II and III. Exposure of cells to MNNG or ENNG at a concentration of 20 mM resulted in reductions in Pol I activity of 40 and 30%, respectively, compared with untreated controls. ENU was slightly inhibitory to Pol I activity, while MMS, EMS, and MNU all caused some enhancement of Pol I activity.These data show that DNA replication in a pseudo-in vivo bacterial system is particularly sensitive to the actions of known chemical mutagens, whereas DNA repair carried out by the Pol I repair enzyme is much less sensitive and in some cases apparently unaffected by such treatment. Possible mechanisms for this differential effect on DNA metabolism and its correlation with current theories of chemically induced mutagenesis and carcinogenesis are discussed.     

Pol kappa partially rescues MMR-dependent cytotoxicity of O6-methylguanine

To maintain genomic integrity cells have to respond properly to a variety of exogenous and endogenous sources of DNA damage. DNA integrity is maintained by the coordinated action of DNA damage response mechanisms and DNA repair. In addition, there are also mechanisms of damage tolerance, such as translesion synthesis (TLS), which are important for survival after DNA damage but are potentially error-prone. Here, we investigate the role of DNA polymerase κ (pol κ) in TLS across alkylated lesions by silencing this polymerase (pol) in human cells using transient small RNA interference. We show that human pol κ has a significant protective role against methyl nitrosourea (MNU)-associated cytotoxicity without affecting significantly mutagenicity. The increase in MNU-induced cytotoxicity when pol κ is down-regulated was affected by the levels of O6-methylguanine DNA methyltransferase and fully abolished when mismatch repair (MMR) was defective. Following MNU treatment, the cell cycle profile was unaffected by the pol κ status. The downregulation of pol κ caused a severe delay in the onset of the second mitosis that was fully dependent on the presence of O6-methylguanine ( O6-meGua) lesions. After MNU exposure, in the absence of pol κ, the frequency of sister chromatid exchanges was unaffected whereas the induction of RAD 51 foci increased. We propose that pol κ partially protects human cells from the MMR-dependent cytotoxicity of O6-meGua lesions by restoring the integrity of replicated duplexes containing single-stranded gaps generated opposite O6-meGua facilitated by RAD 51 binding.     

DNA synthesis and degradation in UV-irradiated toluene treated cells of E. coli K12: The role of polynucleotide ligase

Summary Toluene treated cells have been used to study the processes of DNA synthesis and DNA degradation in ultra-violet irradiated Escherichia coli K12. Synthesis and degradation are both shown to occur extensively if polynucleotide ligase is inhibited, and to occur to a much lesser extent if ligase activity is optimal. Extensive UV-induced DNA synthesis in toluene-treated cells requires ATP for the initial incision step, and DNA polymerase I. Extensive degradation also depends on the early ATP-dependent incision step, and the subsequent degradation shows a partial requirement for ATP. Curtailment of degradation by ligase requires DNA polymerase activity, but is not dependent upon DNA polymerase I. Apparently this process can be carried out with equal facility by either DNA polymerase II or polymerase III. These observations suggest that extensive DNA polymerase I-dependent repair synthesis and extensive DNA degradation are facets of two divergent pathways of excision repair, both of which depend upon the early uvrABC determined ATP-dependent incision step.     

DNA polymerase I-mediated ultraviolet repair synthesis in toluene-treated Escherichia coli.

DNA synthesis after ultraviolet irradiation is low in wild type toluene-treated cells. The level of repair incorporation is greater in strains deficient in DNA polymerase I. The low level of repair synthesis is attributable to the concerted action of DNA polymerase I and polynucleotide ligase. Repair synthesis is stimulated by blocking ligase activity with the addition of nicotinamide mononucleotide (NMN) or the use of a ligase temperature-sensitive mutant. NMN stimulation is specific for DNA polymerase I-mediated repair synthesis, as it is absent in isogenic strains deficient in the polymerase function or the 5' leads to 3' exonuclease function associated with DNA polymerase I. DNA synthesis that is stimulated by NMN is proportional to the ultraviolet exposure at low doses, nonconservative in nature, and is dependent on the uvrA gene product but is independent of the recA gene product. These criteria place this synthesis in the excision repair pathway. The NMN-stimulated repair synthesis requires ATP and is N-ethylmaleimide-resistant. The use of NMN provides a direct means for evaluating the involvement of DNA polymerase I in excision repair.     

Repair response of Escherichia coli to hydrogen peroxide DNA damage.

The repair response of Escherichia coli to hydrogen peroxide-induced DNA damage was investigated in intact and toluene-treated cells. Cellular DNA was cleaved after treatment by hydrogen peroxide as analyzed by alkaline sucrose sedimentation. The incision step did not require ATP or magnesium and was not inhibited by N-ethylmaleimide (NEM). An ATP-independent, magnesium-dependent incorporation of nucleotides was seen after the exposure of cells to hydrogen peroxide. This DNA repair synthesis was not inhibited by the addition of NEM or dithiothreitol. In dnaB(Ts) strain CRT266, which is thermolabile for DNA replication, normal levels of DNA synthesis were found at the restrictive temperature (43 degrees C), showing that DNA replication was not necessary for this DNA synthesis. Density gradient analysis also indicated that hydrogen peroxide inhibited DNA replication and stimulated repair synthesis. The subsequent reformation step required magnesium, did not require ATP, and was not inhibited by NEM, in agreement with the synthesis requirements. This suggests that DNA polymerase I was involved in the repair step. Furthermore, a strain defective in DNA polymerase I was unable to reform its DNA after peroxide treatment. Chemical cleavage of the DNA was shown by incision of supercoiled DNA with hydrogen peroxide in the presence of a low concentration of ferric chloride. These findings suggest that hydrogen peroxide directly incises DNA, causing damage which is repaired by an incision repair pathway that requires DNA polymerase I.     

Short,single-stranded oligonucleotides mediate targeted nucleotide conversion using extracts from isolated liver mitochondria

Site-specific single-nucleotide changes in chromosomal DNA of eukaryotic cells have been achieved using chimeric RNA/DNA oligonucleotides (ONs) and short single-stranded (SS) ONs. However, a variety of human diseases originate from single-point mutations in the genome of mitochondrial DNA. We previously demonstrated that extracts from highly purified rat liver mitochondria possess the essential enzymatic activity to mediate targeted single-nucleotide changes using chimeric ONs in vitro. However, different factor(s) and/or mechanism(s) appear to be involved in SS and RNA/DNA ON mediated DNA repair. Because mitochondria are deficient in certain factors involved in nuclear DNA repair pathways, we investigated whether mitochondria possess the enzymatic machinery for SS ON mediated DNA alterations. Using in vitro DNA repair assays based on mutagenized plasmids and a bacterial read-out system, SS ONs were designed to correct the point mutations in the genes encoded by the different plasmids. In this system, protein extracts from purified rat liver mitochondria and nuclei catalyzed similar levels of site-specific nucleotide modifications using SS ONs. Interestingly, extracts isolated from quiescent liver mediated significantly higher conversion rates than those isolated from regenerating liver. The results suggest that mitochondria contain the factors necessary for correction of single-point mutations by SS ONs. In addition, at least some are different than those required for DNA repair by RNA/DNA ONs. Moreover, correction with SS ONs appears to occur one strand at a time suggesting that repair of the DNA substrate involves strand transfer. The ability of unmodified SS ONs to mediate targeted alteration of the mitochondrial genome may provide a new tactic for treatment of certain mitochondrial-based diseases.     

Effect of DNA polymerase inhibitors on DNA repair in intact and permeable human fibroblasts: evidence that DNA polymerases delta and beta are involved in DNA repair synthesis induced by N-methyl-N'-nitro-N-nitrosoguanidine

The involvement of DNA polymerases alpha, beta, and delta in DNA repair synthesis induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) was investigated in human fibroblasts (HF). The effects of anti-(DNA polymerase alpha) monoclonal antibody, (p-n-butylphenyl)deoxyguanosine triphosphate (BuPdGTP), dideoxythymidine triphosphate (ddTTP), and aphidicolin on MNNG-induced DNA repair synthesis were investigated to dissect the roles of the different DNA polymerases. A subcellular system (permeable cells), in which DNA repair synthesis and DNA replication were differentiated by CsCl gradient centrifugation of BrdUMP density-labeled DNA, was used to examine the effects of the polymerase inhibitors. Another approach investigated the effects of several of these inhibitors on MNNG-induced DNA repair synthesis in intact cells by measuring the amount of [3H]thymidine incorporated into repaired DNA as determined by autoradiography and quantitation with an automated video image analysis system. In permeable cells, MNNG-induced DNA repair synthesis was inhibited 56% by 50 micrograms of aphidicolin/mL, 6% by 10 microM BuPdGTP, 13% by anti-(DNA polymerase alpha) monoclonal antibodies, and 29% by ddTTP. In intact cells, MNNG-induced DNA repair synthesis was inhibited 57% by 50 micrograms of aphidicolin/mL and was not significantly inhibited by microinjecting anti-(DNA polymerase alpha) antibodies into HF nuclei. These results indicate that both DNA polymerases delta and beta are involved in repairing DNA damage caused by MNNG.     

Tests for Deoxyribonucleic Acid Synthesis in Toluenized Bacillus subtilis Cells

Several tests were devised to further characterize deoxyribonucleic acid (DNA) synthesis in toluenized Bacillus subtilis cells. Vigorous agitation of toluenized cells (localization test) demonstrated that the DNA replication is exclusively a cell-associated process. A DNA "repair" condition was also applied to toluenized cells and shown to be distinct from DNA replication in its DNA polymerase I dependency and its ability to synthesize DNA on template which is either cell associated or free, outside the cell. This repair condition was used in conjunction with the localization test to demonstrate the penetration of deoxyribonuclease I and possibly DNA polymerase I into toluenized cells. Therefore, we suggest that the localization test can be used to test the penetration of proteins into toluenized cells for both the DNA repair and replication processes.     

Multiple pathways for repair of hydrogen peroxide-induced DNA damage in Escherichia coli.

The repair response of Escherichia coli to hydrogen peroxide has been examined in mutants which show increased sensitivity to this agent. Four mutants were found to show increased in vivo sensitivity to hydrogen peroxide compared with wild type. These mutants, in order of increasing sensitivity, were recA, polC, xthA, and polA. The polA mutants were the most sensitive, implying that DNA polymerase I is required for any repair of hydrogen peroxide damage. Measurement of repair synthesis after hydrogen peroxide treatment demonstrated normal levels for recA mutants, a small amount for xthA mutants, and none for polA mutants. This is consistent with exonuclease III being required for part of the repair synthesis seen, while DNA polymerase I is strictly required for all repair synthesis. Sedimentation analysis of cellular DNA after hydrogen peroxide treatment showed that reformation was absent in xthA, polA, and polC(Ts) strains but normal in a recA cell line. By use of a lambda phage carrying a recA-lacZ fusion, we found hydrogen peroxide does not induce the recA promoter. Our findings indicate two pathways of repair for hydrogen peroxide-induced DNA damage. One of these pathways would utilize exonuclease III, DNA polymerase III, and DNA polymerase I, while the other would be DNA polymerase I dependent. The RecA protein seems to have little or no direct function in either repair pathway.     

The roles of DNA polymerases alpha, beta, and gamma in DNA repair synthesis induced in hamster and human cells by different DNA damaging agents

The involvement of DNA polymerases alpha, beta, and gamma in DNA repair synthesis was investigated in subcellular preparations of cultured hamster and human cells. A variety of DNA damaging agents, including bleomycin, neocarzinostatin, UV irradiation, and alkylating agents, were utilized to induce DNA repair. The sensitivity of repair synthesis, as well as replicative synthesis and purified DNA polymerase beta activity, to inhibition by the DNA polymerase inhibitors dideoxythymidine triphosphate, aphidicolin, cytosine arabinoside triphosphate, and N-ethylmaleimide was determined. No evidence was obtained for a major role of polymerase gamma in any type of repair synthesis. In both hamster and human cells, the sensitivity of bleomycin- and neocarzinostatin-induced repair synthesis to ddTTP inhibition was essentially identical with that observed for purified polymerase beta, indicating these repair processes proceeded through a mechanism utilizing polymerase beta. Repair synthesis induced by UV irradiation and alkylating agents was not sensitive to ddTTP, indicating repair of these lesions occurred through a pathway primarily utilizing a different DNA polymerase; presumably polymerase alpha. However, replicative synthesis was much more sensitive to polymerase alpha inhibitors than was repair synthesis induced by UV irradiation or alkylating agents. Neither the amount of DNA damage nor the amount of induced repair synthesis influenced the degree to which the different DNA polymerases were involved in repair synthesis. The possibility that "patch size" or the actual type of DNA damage determines the extent to which different polymerases participate in DNA repair synthesis is discussed.     

Purification and characterization of organellar DNA polymerases in the red alga Cyanidioschyzon merolae

DNA polymerase gamma, a mitochondrial replication enzyme of yeasts and animals, is not present in photosynthetic eukaryotes. Recently, DNA polymerases with distant homology to bacterial DNA polymerase I were reported in rice, Arabidopsis, and tobacco, and they were localized to both plastids and mitochondria. We call them plant organellar DNA polymerases (POPs). However, POPs have never been purified in the native form from plant tissues. The unicellular thermotrophic red alga Cyanidioschyzon merolae contains two genes encoding proteins related to Escherichia coli DNA polymerase I (PolA and PolB). Phylogenetic analysis revealed that PolB is an ortholog of POPs. Nonphotosynthetic eukaryotes also have POPs, which suggested that POPs have an ancient origin before eukaryotic photosynthesis. PolA is a homolog of bacterial DNA polymerase I and is distinct from POPs. PolB was purified from the C. merolae cells by a series of column chromatography steps. Recombinant protein of PolA was also purified. Sensitivity to inhibitors of DNA synthesis was different in PolA, PolB, and E. coli DNA polymerase I. Immunoblot analysis and targeting studies with green fluorescent protein fusion proteins demonstrated that PolA was localized in the plastids, whereas PolB was present in both plastids and mitochondria. The expression of PolB was regulated by the cell cycle. The available results suggest that PolB is involved in the replication of plastids and mitochondria.     

Purification and partial characterization of a DNA 3'-phosphatase from Schizosaccharomyces pombe

Cells that depend on oxygen for survival constantly produce reactive oxygen species that attack DNA to produce a variety of lesions, including single-strand breaks with 3'-blocking groups such as 3'-phosphate and 3'-phosphoglycolate. These 3'-blocking ends prevent the activity of DNA polymerase and are generally removed by DNA repair proteins with 3'-diesterase activity. We report here the purification and partial characterization of a 45 kDa protein from Schizosaccharomyces pombe total extract based on the ability of this protein to process bleomycin- or H(2)O(2)-damaged DNA in vitro to allow DNA repair synthesis by DNA polymerase I. Further analysis revealed that the 45 kDa protein removes 3'-phosphate ends created by the Escherichia coli fpg AP lyase following the incision of AP site but is unable to process the 3'-alpha,beta unsaturated aldehyde generated by E. coli endonuclease III. The protein cannot cleave DNA bearing AP sites, suggesting that it is not an AP endonuclease or AP lyase. We conclude that the 45 kDa protein purified from S. pombe is a DNA 3'-phosphatase.     

Fidelity of uracil-initiated base excision DNA repair in DNA polymerase beta-proficient and -deficient mouse embryonic fibroblast cell extracts

Uracil-initiated base excision DNA repair was conducted using homozygous mouse embryonic fibroblast DNA polymerase beta (+/+) and (-/-) cells to determine the error frequency and mutational specificity associated with the completed repair process. Form I DNA substrates were constructed with site-specific uracil residues at U.A, U.G, and U.T targets contained within the lacZalpha gene of M13mp2 DNA. Efficient repair was observed in both DNA polymerase beta (+/+) and (-/-) cell-free extracts. Repair was largely dependent on uracil-DNA glycosylase activity because addition of the PBS-2 uracil-DNA glycosylase inhibitor (Ugi) protein reduced ( approximately 88%) the initial rate of repair in both types of cell-free extracts. In each case, the DNA repair patch size was primarily distributed between 1 and 8 nucleotides in length with 1 nucleotide repair patch constituting approximately 20% of the repair events. Addition of p21 peptide or protein to DNA polymerase beta (+/+) cell-free extracts increased the frequency of short-patch (1 nucleotide) repair by approximately 2-fold. The base substitution reversion frequency associated with uracil-DNA repair of M13mp2op14 (U.T) DNA was determined to be 5.7-7.2 x 10(-4) when using DNA polymerase beta (+/+) and (-/-) cell-free extracts. In these two cases, the error frequency was very similar, but the mutational spectrum was noticeably different. The presence or absence of Ugi did not dramatically influence either the error rate or mutational specificity. In contrast, the combination of Ugi and p21 protein promoted an increase in the mutation frequency associated with repair of M13mp2 (U.G) DNA. Examination of the mutational spectra generated by a forward mutation assay revealed that errors in DNA repair synthesis occurred predominantly at the position of the U.G target and frequently involved a 1-base deletion or incorporation of dTMP.     

Repair of neocarzinostatin-induced deoxyribonucleic acid damage in human lymphoblastoid cells: possible involvement of apurinic/apyrimidinic sites as intermediates

Neocarzinostatin (NCS) induces repair in a xeroderma pigmentosum lymphoblastoid line deficient in the ability to repair DNA damage induced with (acetoxyacetyl-amino)fluorene. Repair was demonstrated by the induction of repair synthesis and by the disappearance of NCS-induced single-strand breaks and/or alkaline-labile sites in DNA. Estimation of NCS-induced repair patch size, based on the density shift induced in DNA by extensive shear after incubation of treated cells in medium with bromodeoxyuridine or by calculation from the extent of restoration of DNA sedimentation profiles in alkaline sucrose gradients and the amount of repair synthesis measured by the BND cellulose method, indicated that only a few nucleotides were inserted per repaired region. NCS-treated bacteriophage T7 DNA requires incubation with alkaline phosphatase to make it a substrate for DNA polymerase I. NCS-reacted T7 DNA, even after phosphatase treatment, is not a substrate for a DNA polymerase alpha obtained from human lymphoma cells. NCS-treated T7 DNA did serve as a substrate for the DNA polymerase alpha when incubated with an apurinic/apyrimidinic (AP) endonuclease with associated 5'-3'-exonuclease activity. The results suggest that NCS-induced AP sites could be intermediates for the in vivo repair synthesis.     

The nature of DNA damage and its repair after treatment of bacteria with dioxidine

The nature of the lethal effect of antimicrobial drug dioxidin was studied. The treatment of bacterial cells by dioxidin results in an instant repression of DNA synthesis and formation of single strand gaps in DNA molecule. The repair of single strand gaps in polA+ cells involves the DNA polymerase I. The deficit of this enzyme leads to the increased degradation of DNA. The products of the recA, polA1, lexA, recB are relevant for bacterial resistance to dioxidin while the products of uvrA, uvrE and recF genes are not. On the basis of the obtained data dioxidin may be defined as a "gamma-type" agent due to the nature of dioxidin-induced lesions in DNA and their repair.     

Evidence that DNA polymerases alpha and beta participate differentially in DNA repair synthesis induced by different agents

The roles of DNA polymerases alpha and beta in DNA replication and repair synthesis were studied in permeable animal cells, using different agents to induce repair synthesis. DNA polymerase inhibitors were used to investigate which polymerases were involved in repair synthesis and in replication. Polymerase alpha was responsible for replication. On the other hand, both polymerases alpha and beta were involved in DNA repair synthesis; the extent to which each polymerase participated depended primarily on the agent used to damage DNA. Polymerase beta was primarily responsible for repair synthesis induced by bleomycin or neocarzinostatin, whereas polymerase alpha played a more prominent role in repair synthesis indiced by N-methyl-N'-nitro-N-nitrosoguanidine or N-nitrosomethyl urea. More DNA damage was induced by the alkylating agents than by bleomycin or neocarzinostatin, suggesting that the extent of involvement of polymerase alpha or beta in DNA repair synthesis is related to the amount or type of DNA damage. In addition, salt concentration was found to have little or no effect on the results obtained with the DNA polymerase inhibitors. Our findings provide an explanation for conflicting reports in the literature concerning the roles of DNA polymerases alpha and beta in DNA repair.