Mutant Escherichia coli Ada proteins simultaneously defective in the repair of O6-methylguanine and in gene activation.

The activated Ada protein triggers expression of DNA repair genes in Escherichia coli in response to alkylation damage. Ada also possesses two distinct suicide alkyltransferase activities, for O6-alkylguanines and for alkyl phosphotriesters in DNA. The mutant Ada3 and Ada5 transferases repair O6-methylguanine in DNA 20 and 3000 times more slowly, respectively, than the wild-type Ada protein, but both exhibit normal DNA phosphotriester repair. These same proteins also exhibit delayed and sluggish induction of the ada and alkA genes. Since the C-terminal O6-methylguanine methyltransferase domain of Ada is not implicated in the direct binding of specific DNA sequences, this part of the Ada protein is likely to play an alternative mechanistic role in gene activation, either by promoting Ada dimerization, or via direct contacts with RNA polymerase.     

Characterization of the major DNA repair methyltransferase activity in unadapted Escherichia coli and identification of a similar activity in Salmonella typhimurium.

Escherichia coli has two DNA repair methyltransferases (MTases): the 39-kilodalton (kDa) Ada protein, which can undergo proteolysis to an active 19-kDa fragment, and the 19-kDa DNA MTase II. We characterized DNA MTase II in cell extracts of an ada deletion mutant and compared it with the purified 19-kDa Ada fragment. Like Ada, DNA MTase II repaired O6-methylguanine (O6MeG) lesions via transfer of the methyl group from DNA to a cysteine residue in the MTase. Substrate competition experiments indicated that DNA MTase II repaired O4-methylthymine lesions by transfer of the methyl group to the same active site within the DNA MTase II molecule. The repair kinetics of DNA MTase II were similar to those of Ada; both repaired O6MeG in double-stranded DNA much more efficiently than O6MeG in single-stranded DNA. Chronic pretreatment of ada deletion mutants with sublethal (adapting) levels of two alkylating agents resulted in the depletion of DNA MTase II. Thus, unlike Ada, DNA MTase II did not appear to be induced in response to chronic DNA alkylation at least in this ada deletion strain. DNA MTase II was much more heat labile than Ada. Heat lability studies indicated that more than 95% of the MTase in unadapted E. coli was DNA MTase II. We discuss the possible implications of these results for the mechanism of induction of the adaptive response. A similarly active 19-kDa O6MeG-O4-methylthymine DNA MTase was identified in Salmonella typhimurium.     

Mutagenic frequencies of site-specifically located O6-methylguanine in wild-type Escherichia coli and in a strain deficient in ada-methyltransferase.

The adaptive response of Escherichia coli involves protection of the cells against the toxic and mutagenic consequences of exposure to high doses of a methylating agent by prior exposure to low doses of the agent. Ada protein, a major repair activity for O6-methylguanine, is activated to positively control the adaptive response; O6-methylguanine is one of the major mutagenic lesions produced by methylating agents. We investigated the mutation frequency of wild-type Escherichia coli and strains containing the ada-5 mutation in response to site-specifically synthesized O6-methylguanine under conditions in which the adaptive response was not induced. Site-directed mutagenesis and oligonucleotide self-selection techniques were used to isolate the progeny of M13mp18 DNAs constructed to contain O6-methylguanine at any of eight different positions. The progeny were isolated from E. coli strains isogeneic except for deficiency in Ada-methyltransferase repair, UvrABC excision repair, or both. The resulting O6-methylguanine mutation levels at each position were determined by using differential oligonucleotide hybridization. We found that the wild type had up to a 2.6-fold higher mutation frequency than ada-5 mutants. In addition, the mutation frequency varied with the position of the O6-methylguanine in the DNA in the wild type but not in ada-5 mutants; O6-methylguanine lesions at the 5' ends of runs of consecutive guanines gave the highest mutation frequencies. Determination of the mutation frequency of O6-methylguanine in wild-type and mutS cells showed that mismatch repair can affect O6-methylguanine mutation levels.     

Methyl phosphotriesters in alkylated DNA are repaired by the Ada regulatory protein of E. coli.

The E. coli ada+ gene product that controls the adaptive response to alkylating agents has been purified to apparent homogeneity using an overproducing expression vector system. This 39 kDa protein repairs 0(6)-methylguanine and 0(4)-methylthymine residues in alkylated DNA by transfer of the methyl group from the base to a cysteine residue in the protein itself. The Ada protein also corrects one of the stereoisomers of methyl phosphotriesters in DNA by the same mechanism, while the other isomer is left unrepaired. Different cysteine residues in the Ada protein are used as acceptors in the repair of methyl groups derived from phosphotriesters and base residues.     

Proteolytic processing of the Ada protein that repairs DNA O6-methylguanine residues in E. coli

In extracts of E. coli treated with an adapting regime of MNNG, the induced 39kd Ada protein having O6-MeG-DNA methyltransferase activity is processed to a 19kd active domain corresponding to the C-terminal half of the intact protein. This proteolytic processing has been followed on Western immunoblots using antisera raised against the 19kd fragment. Initial processing at 25 degrees C or 37 degrees C mainly generates a fragment of mol. wt. 24kd which then undergoes a slower second cleavage to generate the 19kd active domain. Preceding this second cleavage site is a sequence of amino acids Thr- -Gly-Met-Thr- -Lys that also occurs at another site in the N-terminal half of the 39kd methyltransferase. It is proposed that this sequence is a recognition site for proteolytic activity. On the basis of cleavage of the Ada protein at either one or both of these sites, fragments may be generated of mol. wt. 24kd and 19kd containing the active site for O6-methylguanine and O4-methylthymine repair, and 15kd and 20kd, containing the active site for methylphosphotriester repair. These observations explain previous reports by others on the existence in cell extracts of multiple methyltransferase activities of different sizes recognizing O-methyl lesions in DNA. The cellular protease involved is resistant to a wide range of protease inhibitors.     

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.     

Influence of S-Adenosylmethionine Pool Size on Spontaneous Mutation, Dam Methylation, and Cell Growth of Escherichia coli

Escherichia coli strains that are deficient in the Ada and Ogt DNA repair methyltransferases display an elevated spontaneous G:C-to-A:T transition mutation rate, and this increase has been attributed to mutagenic O(6)-alkylguanine lesions being formed via the alkylation of DNA by endogenous metabolites. Here we test the frequently cited hypothesis that S-adenosylmethionine (SAM) can act as a weak alkylating agent in vivo and that it contributes to endogenous DNA alkylation. By regulating the expression of the rat liver SAM synthetase and the bacteriophage T3 SAM hydrolase proteins in E. coli, a 100-fold range of SAM levels could be achieved. However, neither increasing nor decreasing SAM levels significantly affected spontaneous mutation rates, leading us to conclude that SAM is not a major contributor to the endogenous formation of O(6)-methylguanine lesions in E. coli.     

Zinc binding by the methylation signaling domain of the Escherichia coli Ada protein.

The Escherichia coli Ada protein repairs O6-methylguanine residues and methyl phosphotriesters in DNA by direct transfer of the methyl group to a cysteine residue located in its C- or N-terminal domain, respectively. Methyl transfer to the N-terminal domain causes it to acquire a sequence-specific DNA binding activity, which directs binding to the regulatory region of several methylation-resistance genes. In this paper we show that the N-terminal domain of Ada contains a high-affinity binding site for a single zinc atom, whereas the C-terminal domain is free of zinc. The metal-binding domain is apparently located within the first 92 amino acids of Ada, which contains four conserved cysteine residues. We propose that these four cysteines serve as the zinc ligand residues, coordinating the metal in a tetrahedral arrangement. One of the putative ligand residues, namely, Cys69, also serves as the acceptor site for a phosphotriester-derived methyl group. This raises the possibility that methylation-dependent ligand reorganization about the metal plays a role in the conformational switching mechanism that converts Ada from a non-sequence-specific to a sequence-specific DNA-binding protein.     

Purification and structure of the intact Ada regulatory protein of Escherichia coli K12, O6-methylguanine-DNA methyltransferase

The ada gene of Escherichia coli K12, the regulatory gene for the adaptive response of bacteria to alkylating agents, was cloned and placed under the control of the lac regulatory region on a multicopy runaway plasmid, thereby yielding a hybrid plasmid pYN3059. Ada protein with a molecular weight of about 38,000 was overproduced when cells harboring pYN3059 were incubated at 42 degrees C in the presence of a lac inducer, isopropyl-beta-D-thiogalactoside. Taking advantage of overproduction of Ada protein, we purified the protein to apparent physical homogeneity. The purified 38,000-dalton Ada protein transferred the methyl group from the O6-methylguanine residue of alkylated DNA to the Ada protein, per se. Although the Ada protein was degraded to smaller polypeptides when crude extracts or partially purified preparations were incubated in a high ionic-strength buffer at neutral pH, the purified Ada protein remained stable under the same conditions, indicating that the Ada protein may not undergo autodegradation. An amino-terminal sequence and total amino acid composition of the purified Ada protein were in accord with nucleotide sequence of the ada gene, determined by the dideoxy method using M13 phage. It was deduced that Ada protein comprises 354 amino acids and its molecular weight is 39,385. The promoter for the ada gene was determined by S1 nuclease mapping.     

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.     

Suicide inactivation of the E. coli O6-methylguanine-DNA methyltransferase

The O6-methylguanine-DNA methyltransferase of Escherichia coli acts rapidly and stoichiometrically to convert a mutagenic O6-methylguanine residue in DNA to unsubstituted guanine. Even at low protein concentrations and in the absence of any cofactors, the transfer of a methyl group to one of the protein's own cysteine residues occurs in less than 2 s at 37 degrees C. The entire kinetic process can be followed experimentally at 5 degrees C. Formation of S-methylcysteine in the protein is accompanied by loss of activity and accounts for the exceptional suicide kinetics of this enzyme as well as for the sharp saturation of O6-methylguanine repair observed in vivo. The enzyme can remove greater than 98% of the methyl groups from O6-methylguanine present in alkylated DNA, but leaves N-alkylated purines untouched. Single-stranded DNA containing O6-methylguanine is a poor substrate, with the methyl transfer occurring at approximately 0.1% of the rate for duplex DNA. This latter observation may explain the high frequency of mutations induced by alkylating agents at DNA replication forks.     

Relative efficiencies of the bacterial, yeast, and human DNA methyltransferases for the repair of O6-methylguanine and O4-methylthymine. Suggestive evidence for O4-methylthymine repair by eukaryotic methyltransferases

The suicidal inactivation mechanism of DNA repair methyltransferases (MTases) was exploited to measure the relative efficiencies with which the Escherichia coli, human, and Saccharomyces cerevisiae DNA MTases repair O6-methylguanine (O6MeG) and O4-methylthymine (O4MeT), two of the DNA lesions produced by mutagenic and carcinogenic alkylating agents. Using chemically synthesized double-stranded 25-base pair oligodeoxynucleotides containing a single O6MeG or a single O4MeT, the concentration of O6MeG or O4MeT substrate that produced 50% inactivation (IC50) was determined for each of four MTases. The E. coli ogt gene product had a relatively high affinity for the O6MeG substrate (IC50 8.1 nM) but had an even higher affinity for the O4MeT substrate (IC50 3 nM). By contrast, the E. coli Ada MTase displayed a striking preference for O6MeG (IC50 1.25 nM) as compared to O4MeT (IC50 27.5 nM). Both the human and the yeast DNA MTases were efficiently inactivated upon incubation with the O6MeG-containing oligomer (IC50 values of 1.5 and 1.3 nM, respectively). Surprisingly, the human and yeast MTases were also inactivated by the O4MeT-containing oligomer albeit at IC50 values of 29.5 and 44 nM, respectively. This result suggests that O4MeT lesions can be recognized in this substrate by eukaryotic DNA MTases but the exact biochemical mechanism of methyltransferase inactivation remains to be determined.     

Cloning of the E. coli O6-methylguanine and methylphosphotriester methyltransferase gene using a functional DNA repair assay.

Alkylating agents react with various nitrogen and oxygen atoms in DNA and many of the products are substrates for repair processes. Oxygen atom derivatives such as O6-methylguanine (O6-meG) O4-methylthymine and methylphosphotriesters (MP) have been shown to undergo repair by methyl group removal. The proteins involved in the latter reaction can be considered to be methyltransferases (MT) because their action results in the transfer of the methyl group to a cysteine residue within a polypeptide. A rapid and sensitive assay for MT activity has been developed and used to screen extracts of bacteria harbouring an E. coli genomic DNA library carried in a plasmid vector. We report here the cloning of an E. coli gene coding for O6-meG and MP MT repair functions. These two activities reside on a 37Kd protein that can undergo a host-dependent cleavage to produce an 18Kd protein which contains only O6-meG MT and a 13Kd protein which contains only MP MT.     

Reaction and binding of oligodeoxynucleotides containing analogues of O6-methylguanine with wild-type and mutant human O6-alkylguanine-DNA alkyltransferase.

O6-Alkylguanine-DNA alkyltransferase (AGT) repairs DNA by transferring the methyl group from the 6-position of guanine to a cysteine residue on the protein. We previously found that the Escherichia coli Ada protein makes critical interactions with O6-methylguanine (O6mG) at the N1- and O6-positions. Human AGT has a different specificity than the bacterial protein. We reacted hAGT with double-stranded pentadecadeoxynucleotides containing analogues of O6mG. The second-order rate constants were in the following order (x10(-)5 M-1 s-1): O6mG (1.4), O6-methylhypoxanthine (1.6) > Se6-methyl-6-selenoguanine (0.1) > S6-methyl-6-thioguanine (S6mG) (0.02) > S6-methyl-6-thiohypoxanthine (S6mH), O6-methyl-1-deazaguanine (O6m1DG), O6-methyl-3-deazaguanine (O6m3DG), and O6-methyl-7-deazaguanine (O6m7DG) (all <0.0001). Electrophoretic mobility shift assays were carried out to determine the binding affinity to hAGT. Oligodeoxynucleotides containing O6mG, S6mG and O6m3DG bound to AGT in the presence of competitor DNA with Kd values from 5 to 20 microM, while those containing G, S6mH, O6m1DG, and O6m7DG did not (Kd > 200 microM). These results indicate that the 1-, N2-, and 7- positions of O6mG are critical in binding to hAGT, while the 3- and O6-positions are involved in methyl transfer. These results suggest that the active site of ada AGT is more flexible than hAGT and may be the reason ada AGT reacts with O4mT faster than hAGT.     

Separation of the SOS-dependent and SOS-independent components of alkylating-agent mutagenesis.

Escherichia coli plasmids containing the rpsL+ gene (Strs phenotype) as the target for mutation were treated in vitro with N-methyl-N-nitrosourea. Following fixation of mutations in E. coli MM294A cells (recA+ Strs), an unselected population of mutant and wild-type plasmids was isolated and transferred into a second host, E. coli 6451 (recA Strr). Strains carrying plasmid-encoded forward mutations were then selected as Strr isolates, while rpsL+ plasmids conferred the dominant Strs phenotype in the second host. Mutation induction and reduced survival of N-methyl-N-nitrosourea-treated plasmids were shown to be dose dependent. Because this system permitted analysis and manipulation of the levels of certain methylated bases produced in vitro by N-methyl-N-nitrosourea, it afforded the opportunity to assess directly the relative roles of these bases and of SOS functions in mutagenesis. The methylated plasmid DNA gave a mutation frequency of 6 X 10(-5) (a 40-fold increase over background) in physiologically normal cells. When the same methylated plasmid was repaired in vitro by using purified O6-methylguanine DNA methyltransferase (to correct O6-methylguanine and O4-methylthymine), no mutations were detected above background levels. In contrast, when the methylated plasmid DNA was introduced into host cells induced by UV light for the SOS functions, rpsL mutagenesis was enhanced eightfold over the level seen without SOS induction. This enhancement of mutagenesis by SOS was unaffected by prior treatment of the DNA with O6-methylguanine DNA methyltransferase. These results demonstrate a predominant mutagenic role for alkylation lesions other than O6-methylguanine or O4-methylthymine when SOS functions are induced. The mutation spectrum of N-methyl-N-nitrosourea under conditions of induced SOS functions revealed a majority of mutagenic events at A . T base pairs.     

Active site amino acid sequence of the bovine O6-methylguanine-DNA methyltransferase.

An O6-methylguanine-DNA methyltransferase has been partially purified from calf thymus by conventional biochemical techniques. The enzyme was specifically radioactively labelled at the cysteine residue of the active site and further purified by attachment to a solid support. Following digestion with trypsin, a radioactive peptide containing the active site region of the protein was purified by size fractionation, ion exchange chromatography and reverse phase HPLC. The technique yielded an essentially homogeneous oligopeptide which was subjected to amino acid sequencing. The sequence adjacent to the acceptor cysteine residue of the bovine protein exhibits striking homology to the C-terminal methyl acceptor site of the E. coli Ada protein and the proposed acceptor sites of the E. coli Ogt and the B. subtilis Dat1 proteins.     

Site directed mutagenesis of two cysteine residues in the E. coli ogt O6-alkylguanine DNA alkyltransferase protein.

The E. coli ogt O6-alkylguanine-DNA alkyltransferase has two cysteine residues positioned identically with respect to cysteines in the E. coli ada O6-alkylguanine-DNA alkyltransferase. In order to assess their function, these residues were each substituted by a glycine to generate altered forms of the ogt protein. Mutagenesis of cysteine-139, located within a 'PCHRV' region of homology, eliminated functional activity confirming that this residue is the methyl-accepting cysteine in the active site of the protein. Substitution of cysteine 102 within the sequence 'LRTIPCG' had little effect on the ogt protein activity demonstrating that this cysteine is not directly involved with the transfer of O6-methylguanine adducts.