Complementation of sensitivity to alkylating agents in Escherichia coli and Chinese hamster ovary cells by expression of a cloned bacterial DNA repair gene.

Dual expression vectors derived from pSV2gpt and encoding all or part of the Escherichia coli ada+ gene have been constructed. Following transformation into an E. coli ada strain or transfection and stable integration into the genome of Chinese hamster ovary (CHO) cells, plasmid vectors containing the whole ada+ gene conferred resistance to both killing and mutagenesis by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). Thus, the bacterial DNA repair gene was functionally expressed in the mammalian cells. Plasmids containing an N-terminal fragment of the ada+ gene which encoded only one of the two methyltransferase activities of the Ada protein did not significantly protect E. coli or CHO cells against MNNG. These results are consistent with the central role of the intact ada+ gene in controlling the adaptive response to alkylating agents in E. coli. However, the data further suggest that some alkylation lesions in DNA, such as O6-methylguanine, may exert partly different biological effects in E. coli and mammalian cells.     

Induction of transversion mutations in Escherichia coli by N-methyl-N''-nitro-N-nitrosoguanidine is SOS dependent.

Escherichia coli alkA mutants, which are deficient for an inducible DNA glycosylase, 3-methyladenine-DNA glycosylase II, are sensitive to mutagenesis by low doses of the alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). As many as 90% of the alkA-dependent mutations induced by MNNG are also umuC+ dependent and thus are due to DNA lesions that are substrates for the mutagenic functions of the SOS response. A great number of these mutations are base substitutions at A . T sites, particularly A . T transversions. We discuss which DNA lesions may be responsible for these mutations. Our results show that the induction of 3-methyladenine-DNA glycosylase II, which occurs as part of the adaptive response to alkylating agents such as MNNG, significantly reduces the mutagenicity as well as the lethality of alkylation damage.     

The adaptive response of E.coli to low levels of alkylating agent: the role of polA in killing adaptation.

Summary In an attempt to characterise which gene products may be involved in the repair system induced in E. coli by growth on low levels of alkylating agent (the adaptive response) we have analysed mutants deficient in other known pathways of DNA repair for the ability to adapt to MNNG. Adaptive resistance to the killing effects of MNNG seems to require a functional DNA polymerase I whereas resistance to the mutagenic effects can occur in polymerase I deficient strains; similarly killing adaptation could not be observed in a dam3 mutant, which was nonetheless able to show mutational adaptation. These results suggest that these two parts of the adaptive response must, at least to some extent, be separable. Both adaptive responses can be seen in the absence of uvrD ⁺ uvrE ⁺-dependent mismatch repair, DNA polymerase II activity, or recF-mediated recombination and they are not affected by decreased levels of adenyl cyclase. The data presented support our earlier conclusion that adaptive resistance to the killing and mutagenic effect of MNNG is the result of previously uncharacterised repair pathways.     

Increased spontaneous mutation and alkylation sensitivity of Escherichia coli strains lacking the ogt O6-methylguanine DNA repair methyltransferase.

Escherichia coli expresses two DNA repair methyltransferases (MTases) that repair the mutagenic O6-methylguanine (O6MeG) and O4-methylthymine (O4MeT) DNA lesions; one is the product of the inducible ada gene, and here we confirm that the other is the product of the constitutive ogt gene. We have generated various ogt disruption mutants. Double mutants (ada ogt) do not express any O6MeG/O4MeT DNA MTases, indicating that Ada and Ogt are probably the only two O6MeG/O4MeT DNA MTases in E. coli. ogt mutants were more sensitive to alkylation-induced mutation, and mutants arose linearly with dose, unlike ogt+ cells, which had a threshold dose below which no mutants accumulated; this ogt(+)-dependent threshold was seen in both ada+ and ada strains. ogt mutants were also more sensitive to alkylation-induced killing (in an ada background), and overexpression of the Ogt MTase from a plasmid provided ada, but not ada+, cells with increased resistance to killing by alkylating agents. The induction of the adaptive response was normal in ogt mutants. We infer from these results that the Ogt MTase prevents mutagenesis by low levels of alkylating agents and that, in ada cells, the Ogt MTase also protects cells from killing by alkylating agents. We also found that ada ogt E. coli had a higher rate of spontaneous mutation than wild-type, ada, and ogt cells and that this increased mutation occurred in nondividing cells. We infer that there is an endogenous source of O6MeG or O4MeT DNA damage in E. coli that is prevalent in nondividing cells.     

The human cyclin B1 protein modulates sensitivity of DNA mismatch repair deficient prostate cancer cell lines to alkylating agents

DNA damage caused by alkylating agents results in a G2 checkpoint arrest. DNA mismatch repair (MMR) deficient cells are resistant to killing by alkylating agents and are unable to arrest the cell cycle in G2 phase after alkylation damage. We investigated the response of two MMR-deficient prostate cancer cell lines DU145 and LNCaP to the alkylating agent MNNG. Our studies reveal that DU145 cancer cells are more sensitive to killing by MNNG than LNCaP. Investigation of the underlying reasons for lower resistance revealed that the DU145 cells contain low endogenous levels of cyclin B1. We provide direct evidence that the endogenous level of cyclin B1 modulates the sensitivity of MMR-deficient prostate cancer cells to alkylating agents.     

Genetic recombination of bacterial plasmid DNA: effect of RecF pathway mutations on plasmid recombination in Escherichia coli.

Tn5 insertion mutations in the recN gene, and in what appears to be a new RecF pathway gene designated recO and mapping at approximately 55.4 min on the standard genetic map, were isolated by screening Tn5 insertion mutations that cotransduced with tyrA. The recO1504::Tn5 mutation decreased the frequency of recombination during Hfr-mediated crosses and increased the susceptibility to killing by UV irradiation and mitomycin C when present in a recB recC sbcB background, but only increased the sensitivity to killing by UV irradiation when present in an otherwise Rec+ background. The effects of these and other RecF pathway mutations on plasmid recombination were tested. Mutations in the recJ, recO, and ssb genes, when present in otherwise Rec+ E. coli strains, decreased the frequency of plasmid recombination, whereas the lexA3, recAo281, recN, and ruv mutations had no effect on plasmid recombination. Tn5 insertion mutations in the lexA gene increased the frequency of plasmid recombination. These data indicate that plasmid recombination events in wild-type Escherichia coli strains are catalyzed by a recombination pathway that is related to the RecF recombination pathway and that some component of this pathway besides the recA gene product is regulated by the lexA gene product.     

Expression of the E.coli ada gene in S.cerevisiae provides cellular resistance to N-methyl-N'-nitro-N-nitrosoguanidine in rad6 but not in rad52 mutants.

The Escherichia coli ada gene protein coding region under the control of the yeast alcohol dehydrogenase promoter in the extrachromosomally replicating yeast expression vectors pADHO6C and pVT103LO6C was introduced into the wild-type yeast strains, YNN-27 and FF-18733, and the repair deficient mutants LN-1 (rad1-1), VV-5 (rad6-1), C5-6 (rad52-1) and FF-18742 (rad52::URA3). This resulted in the expression of 3950, 1900, 1870, 1620, 1320 and 1420 fmol ada-encoded ATase/mg protein respectively: transformation with the parent vectors resulted in ATase activities of 3-17 fmol/mg protein. The wild-types, rad1-1 and rad6-1 yeast expressing the bacterial ATase showed increased resistance to the toxic and mutagenic effects of N-methyl-N'-nitro-N- nitrosoguanidine (MNNG). Expression of ATase in the rad52-1 and rad52::URA3 mutants neither complemented their sensitivity, nor reduced the mutagenic effects of this agent. These results suggest that whilst a portion of the toxic and mutagenic lesions induced by MNNG can be repaired in yeast by the E.coli Ada protein in a RAD1- and RAD6-independent manner, the RAD52 gene product may be essential for the complete functioning of the Ada ATase. This is the first suggestion of a possible cofactor requirement for ATase.     

Pseudomonas putida AlkA and AlkB Proteins Comprise Different Defense Systems for the Repair of Alkylation Damage to DNA – In Vivo,In Vitro,and In Silico Studies

Alkylating agents introduce cytotoxic and/or mutagenic lesions to DNA bases leading to induction of adaptive (Ada) response, a mechanism protecting cells against deleterious effects of environmental chemicals. In Escherichia coli, the Ada response involves expression of four genes: ada, alkA, alkB, and aidB. In Pseudomonas putida, the organization of Ada regulon is different, raising questions regarding regulation of Ada gene expression. The aim of the presented studies was to analyze the role of AlkA glycosylase and AlkB dioxygenase in protecting P. putida cells against damage to DNA caused by alkylating agents. The results of bioinformatic analysis, of survival and mutagenesis of methyl methanesulfonate (MMS) or N-methyl-N’-nitro-N-nitrosoguanidine (MNNG) treated P. putida mutants in ada, alkA and alkB genes as well as assay of promoter activity revealed diverse roles of Ada, AlkA and AlkB proteins in protecting cellular DNA against alkylating agents. We found AlkA protein crucial to abolish the cytotoxic but not the mutagenic effects of alkylans since: (i) the mutation in the alkA gene was the most deleterious for MMS/MNNG treated P. putida cells, (ii) the activity of the alkA promoter was Ada-dependent and the highest among the tested genes. P. putida AlkB (PpAlkB), characterized by optimal conditions for in vitro repair of specific substrates, complementation assay, and M13/MS2 survival test, allowed to establish conservation of enzymatic function of P. putida and E. coli AlkB protein. We found that the organization of P. putida Ada regulon differs from that of E. coli. AlkA protein induced within the Ada response is crucial for protecting P. putida against cytotoxicity, whereas Ada prevents the mutagenic action of alkylating agents. In contrast to E. coli AlkB (EcAlkB), PpAlkB remains beyond the Ada regulon and is expressed constitutively. It probably creates a backup system that protects P. putida strains defective in other DNA repair systems against alkylating agents of exo- and endogenous origin.     

The partial recA-lexA dependence of the adaptive response of Escherichia coli to exposure to methylmethane sulfonate

A study was made of the adaptive response to methylmethane sulfonate (MMS) in E. coli. (18 strains of B, WP2, and H/r30 groups, including three strains of bacteria with pKM101 plasmid). The adaptation of wild type cells and uvrA- and uvrB- mutants to non-lethal concentrations of MMS (10-30 mkg/ml during 90-120 min) leads to a significant increase in their resistance to lethal MMS concentrations (10-30 mM for 10-120 min): the dose modifying factor (DMF) being 1.5-1.8. In single recA or lexA mutants (or double recA uvr- and lexA uvr- mutants) the efficiency of adaptive response to MMS was significantly lower: the DMF being 1.1-1.2. In Bs-1 gamma R strain with intragenic suppressor of lexA gene the adaptive response efficiency was the same as in B/r (recA+lexA+) strain. There is no adaptive response to MMS in polA- strains. The adaptive response to MMS in E. coli is different from that to N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) and N-methylnitrosourea (MNM), because in these two cases it is absolutely lexA-recA dependent. It is supposed that a partial recA-lexA dependence of the adaptive response to MMS in E. coli may be due to a specific MMS-induced lethal damage that induces an adaptive repair non-related to the system of recA-lexA-independent adaptive responses to MNNG and MNM. The presence of a plasmid of drug resistance pKM101 exerts no influence on the value, efficiency and recA-lexA-dependence of the adaptive response of E. coli to MMS.     

Mutagenic action of alkylating agents on prophage lambda

The lethal and mutagenic effects of 7 alkylating agents: N-nitroso-N-methylurea (NMU), N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS), nitrogen mustard (HN2), mitomycin C (MC), bifunctional acridine mustard (AM)--and of cyanate (KNCO) on heat inducible lambda cI857 prophage were studied. After treatment of lysogenic cells with mutagens, prophage was heat-induced either immediately or after 90 min incubation in nutrient broth and c mutants forming clear plaques at 32 degrees C were scored. NMU (0.02 M) when immediately induced with heat, induces c mutants very efficiently (maximal yield 10%) not only in the wild-type cells but also in repair-deficient mutants recA13, lexA102, uvrA6 umuC36, recF143, xthA9, polA1, uvrD3 and uvrD502. These data show that NMU-induced mutations are fixed as replication errors due to mispairing modified bases. After delayed heat induction, the prophage survival enhances and the frequency of c mutations declines considerably in host cells of all repair genotypes tested. Carbamoylation is not involved in the mutagenic action of NMU, because KNCO (0.02 M) has a very slight lethal effect and does not induce mutations. MNNG (100 micrograms/ml) and EMS (0.1 M) also induce mutations by replicative mechanism, because maximal yield of c mutations does not depend on RecA+ and is about 15 and 2%, respectively. MMS is a mutagen of the repair type, since its mutagenic action is suppressed by recA mutation of the host. NH2 only inactivates prophage, but does not induce mutations. MC (50 micrograms/ml) and AM (150 micrograms/ml) induce mutations rather inefficiently (the maximal yield 0.1 and 0.3%, respectively) both in recA+ and recA- hosts. The mutagenic action of these agents is probably due to intercalation.     

Construction and characterization of mutants of Salmonella typhimurium deficient in DNA repair of O6-methylguanine.

Escherichia coli has two O6-methylguanine DNA methyltransferases that repair alkylation damage in DNA and are encoded by the ada and ogt genes. The ada gene of E. coli also regulates the adaptive response to alkylation damage. The closely related species Salmonella typhimurium possesses methyltransferase activities but does not exhibit an adaptive response conferring detectable resistance to mutagenic methylating agents. We have previously cloned the ada-like gene of S. typhimurium (adaST) and constructed an adaST-deletion derivative of S. typhimurium TA1535. Unexpectedly, the sensitivity of the resulting strain to the mutagenic action of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) was similar to that of the parent strain. In this study, we have cloned and sequenced the ogt-like gene of S. typhimurium (ogtST) and characterized ogtST-deletion derivatives of TA1535. The ogtST mutant was more sensitive than the parent strain to the mutagenicity of MNNG and other simple alkylating agents with longer alkyl groups (ethyl, propyl, and butyl). The adaST-ogtST double mutant had a level of hypersensitivity to these agents similar to that of the ogtST single mutant. The ogtST and the adaST-ogtST mutants also displayed a two to three times higher spontaneous mutation frequency than the parent strain and the adaST mutant. These results indicate that the OgtST protein, but not the AdaST protein, plays a major role in protecting S. typhimurium from the mutagenic action of endogenous as well as exogenous alkylating agents.     

Generation of an endogenous DNA-methylating agent by nitrosation in Escherichia coli.

Escherichia coli ada ogt mutants, which are totally deficient in O6-methylguanine-DNA methyltransferases, have an increased spontaneous mutation rate. This phenotype is particularly evident in starving cells and suggests the generation of an endogenous DNA alkylating agent under this growth condition. We have found that in wild-type cells, the level of the inducible Ada protein is 20-fold higher in stationary-phase and starving cells than in rapidly growing cells, thus enhancing the defense of these cells against DNA damage. The increased level of Ada in stationary cells is dependent on RpoS, a stationary-phase-specific sigma subunit of RNA polymerase. We have also identified a potential source of the mutagenic agent. Nitrosation of amides and related compounds can generate directly acting methylating agents and can be catalyzed by bacteria] enzymes. E. coli moa mutants, which are defective in the synthesis of a molybdopterin cofactor required by several reductases, are deficient in nitrosation activity. It is reported here that a moa mutant shows reduced generation of a mutagenic methylating agent from methylamine (or methylurea) and nitrite added to agar plates. Moreover, a moa mutation eliminates much of the spontaneous mutagenesis in ada ogt mutants. These observations indicate that the major endogenous mutagen is not S-adenosylmethionine but arises by bacterially catalyzed nitrosation.     

Isolation and partial characterization of human cell mutants differing in sensitivity to killing and mutation by methylnitrosourea and N-methyl-N'-nitro-N-nitrosoguanidine

Isogenic variants resistant to alkylating agents have been isolated from the human lymphoblast cell line TK6. The cell lines may be divided into four classes on the basis of resistance to N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). The sensitive TK6 parental line shows a 37% survival after 45-min exposure to 0.04 microM MNNG; the three classes of more resistant mutants show 37% survival after 45-min exposure to 2 microM (MF lines), 6 microM (MT lines), and greater than or equal to 10 microM (MX line) MNNG. A representative MF line, MF1, is resistant to both killing and mutation by MNNG or N-methyl-N-nitrosourea. An MT clone, MT1, is highly resistant to killing but hypermutable by MNNG. The MT1 line, like the parental TK6, does not remove O6-methylguanine adducts from the DNA. Our data are consistent with the hypothesis that the MT1 line possesses a nonexcision pathway of defense against killing by alkylating agents. Rather than preventing alkylation of DNA or removing alkylated adducts, the MT1 cells appear to be tolerant of the adducts that are not removed from the DNA.     

Enhanced Resistance to Nitrosoguanidine Killing and Mutagenesis in a DNA Gyrase Mutant of Escherichia coli

The role of DNA gyrase in handling DNA damages induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) was examined with two Escherichia coli strains, KL161 and KL166. The two strains are isogenic except that KL166 harbors a mutation at the nalA (gyrA) locus which specifies one of the two subunits of DNA gyrase. We treated the two strains with several different types of mutagenic agents and found the nalA strain to be highly resistant to MNNG-induced killing and mutagenic effects as compared with the parental strain. The MNNG resistance was specific, since the two strains were about equally sensitive to methyl methane sulfonate, ethyl methane sulfonate, and UV and gamma radiations. We pulse-labeled the two strains with [(3)H]uridine and (14)C-amino acids after MNNG treatment to analyze RNA and protein synthetic rates. The pulse-labeled proteins were also separated on polyacrylamide gels. The results show that pulse-labeled RNA and proteins persisted in the nalA strain but declined rapidly in the parental strain after MNNG treatment. We compared membrane-free nucleoid preparations from the two strains by sucrose density gradient centrifugation and found a difference in nucleoid organization between the two strains. The nucleoid of the nalA strain, unlike that of the parental strain, may have a highly ordered structure, as indicated by its resistance to ethidium bromide-induced relaxation. The ability of the two strains to express an adaptive response to MNNG was determined. We found that the resistance to MNNG killing and mutagenesis by the nalA strain cannot be further increased by adaptive treatment. These results suggest that an alteration in DNA gyrase may have profound effects on E. coli chromosome organization and base methylation by MNNG.     

Repair of platinum-DNA lesions in E. coli by a pathway which does not recognize DNA damage caused by MNNG or UV light

The adaptive response is an inducible DNA-repair system which diminishes the mutagenic and toxic effects of alkylating agents. A mutant of E. coli constitutive for adaptative repair, BS21, has been isolated. A spontaneous revertant of this strain, BS23, lacks the adaptive response. When compared to its wild-type parent, mutant BS21 showed an increased resistance to the killing and mutagenic effects of a compound which is not a classical alkylating agent, the antitumor drug cis-diamminedichloroplatinum(II) (cis-DDP). However, this resistance to cis-DDP was also found in strain BS23 which lacks the adaptive response. cis-DDP bound to the DNA of all 3 strains with the same efficiency. In addition, we have investigated the effect of UV radiation and we failed to observe a significant difference in the survival and mutagenesis of these strains. This evidence suggests that the resistance of BS21 and BS23 strains to cis-DDP is not a consequence of the adaptive response or increased excision repair.     

Expression of the E.coli ada gene in yeast protects against the toxic and mutagenic effects of N-methyl-N''-nitro-N-nitrosoguanidine.

The E.coli ada gene protein coding region has been ligated into an extrachromosomally replicating yeast expression vector downstream of the yeast alcohol dehydrogenase gene promoter region to produce pADH06C. The yeast strains SX46A, 7799-4B and VV-6 are deficient in endogenous O6-alkylguanine-DNA-alkyltransferase and transformation of these strains with this shuttle vector resulted in the expression of 1730, 1260 and 374 fmoles ada-encoded ATase/mg protein in stationary phase yeast: transformation with the parent vector had no effect on endogenous ATase activity which remained less than 2 fm/mg. In comparison with parent vector transformed yeast, all of the pADH06C-transformed strains showed an increase in the resistance to the toxic effects of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). In addition, 7799-4B and VV-6 were more resistant to the mutagenic effects of this agent. These results indicate that the toxic and mutagenic effects of MNNG in yeast are mediated, at least in part, by DNA lesions than can be repaired by the E.coli ada gene product.     

Rates of micronuclei induction in different mouse strains

It has previously been shown that the inbred mouse strain MS/Ae was more sensitive in the micronucleus test to several mutagenic agents than outbred mice. To elucidate the possible influence of inbreeding, several inbred strains including MS/Ae, AKR, BALB/c, C57 BR were compared to the two OF1 and NMRI outbred strains. The 3 mutagenic agents MNNG, MMC and MMS all induced a significantly higher number of micronuclei in the MS/Ae strain than in any of the other mouse strains. AKR was especially resistant to the alkylating agents MMS and MNNG. Hence, except for the MS/Ae mouse strain, no inbred strain showed a systematically higher sensitivity than the outbred strains for all of the 3 mutagenic agents used.     

Repeated doses of gamma rays induce resistance to N-methyl-N'-nitro-N-nitrosoguanidine in Chinese hamster cells

Chinese hamster V79 cells were preirradiated repeatedly with gamma rays and then exposed to ultraviolet (uv) light or N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). The cell killing and induction of mutation at the hypoxanthine-guanine phosphoribosyltransferase locus were examined following these treatments. Cells preirradiated with multiple fractions of gamma rays exhibit the same sensitivity to uv light as the control cells with respect to cell survival and mutation induction. Following treatment with MNNG, resistance to cell killing was observed along with a decreased frequency of mutations induced. These results indicate that the progeny of cells irradiated with multiple fractions of gamma rays could display subsequent changes in sensitivity to lethal and mutagenic effects of additional treatment with DNA-damaging agents.