The Adaptive Response to Alkylation Damage

Evidence for a weak adaptive response to alkylation damage in Vibrio cholerae

Wild-type Vibrio cholerae cells, when adapted by a stepwise treatment with sub-lethal concentrations of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), acquired resistance to killing and mutagenesis by subsequent challenges with higher concentrations of MNNG. This was also seen in the rec isogenic strain indicating that the observed phenomenon was not due to the induction of SOS functions. Further, the adapted cells of both the wild-type and rec strains could reactivate lethally alkylated phages with equal efficiency. Increased resistance of adapted cells correlated with the induction of a 17-kDa DNA methyltransferase, capable of repairing O6-methylguanine lesions in DNA. This induced methyltransferase was found to be antigenically unrelated to the Escherichia coli methyltransferase (Ada protein) as determined by Western blotting with polyclonal antiserum raised against the E. coli protein. Even though no counterpart of the constitutively expressed methyltransferase (Ogt) of E. coli could be detected in V. cholerae, several lines of evidence pointed towards the presence of an E. coli alk A-like gene in the organism.

The effects of N7-methylguanine on duplex DNA structure

BACKGROUND

Non-enzymatic methylation of DNA by endogenous and exogenous agents produces a variety of adducts, of which the predominant one is N7-methyl-2'-deoxyguanosine (m7dG). Although it is known that living organisms counter the deleterious effects of m7dG by producing adduct-specific DNA repair proteins, the molecular basis for specific recognition and catalysis by these proteins is poorly understood. In addition to its role as an endogenous DNA adduct, m7dG is also widely used as an in vitro probe of protein-DNA interactions. We set out to examine whether incorporation of m7dG into DNA affects duplex DNA structure.

RESULTS

We carried out a large-scale synthesis of a dodecamer containing the m7dG adduct at a single, defined position. Because the instability of m7dG precludes its incorporation into oligonucleotides by standard solid-phase methods, a novel strategy employing chemical and enzymatic synthesis was used. Characterization of the m7dG-containing dodecamer by NMR reveals no structural distortion; indeed, m7dG appears to encourage a modest shift toward a more characteristically B-form duplex.

CONCLUSIONS

These results argue strongly against induced DNA distortion as a mechanism for specific recognition of m7dG by adduct-specific repair proteins. The broad substrate specificity of these repair proteins disfavors a model involving direct recognition of aberrantly placed methyl groups; hence, it may be that m7dG is recognized indirectly, perhaps by its effects on the dynamics of DNA. On the other hand, the evidence presented here suggests that m7dG interferes directly with sequence-specific recognition by DNA-binding proteins by steric blockage or by masking of required contact functionalities. The synthetic methodology used here should be generally applicable to high-resolution structural studies of oligonucleotides bearing adducts that are unstable to the conditions of solid-phase DNA synthesis.

Molecular analysis of Bacillus subtilis ada mutants deficient in the adaptive response to simple alkylating agents

Previously, we isolated and characterized six Bacillus subtilis ada mutants that were hypersensitive to methylnitroso compounds and deficient in the adaptive response to alkylation. Cloning of the DNA complementing the defects revealed the presence of an ada operon consisting of two tandem and partially overlapping genes, adaA and adaB. The two genes encoded proteins with methylphosphotriester-DNA methyltransferase and O6-methylguanine-DNA methyltransferase activities, respectively. To locate the six mutations, the ada operon was divided into five overlapping regions of about 350 bp. The fragments of each region were amplified by polymerase chain reaction and analyzed by gel electrophoresis to detect single-strand conformation polymorphism. Nucleotide sequences of the fragments exhibiting mobility shifts were determined. Three of the mutants carried sequence alterations in the adaA gene: the adaA1 and adaA2 mutants had a one-base deletion and insertion, respectively, and the adaA5 mutant had a substitution of two consecutive bases causing changes of two amino acid residues next to the presumptive alkyl-accepting Cys-85 residue. Three mutants carried sequence alterations in the adaB gene: the adaB3 mutant contained a rearrangement, the adaB6 mutant contained a base substitution causing a change of the presumptive alkyl-accepting Cys-141 to Tyr, and the adaB4 mutant contained a base substitution changing Leu-167 to Pro. The adaB mutants produced ada transcripts upon treatment with low doses of alkylating agents, whereas the adaA mutant did not. We conclude that the AdaA protein functions as the transcriptional activator of this operon, while the AdaB protein specializes in repair of alkylated residues in DNA.

A weak adaptive response to alkylation damage in Salmonella typhimurium

An efficient adaptive response to alkylation damage was observed in several enterobacterial species, including Klebsiella aerogenes, Shigella sonnei, Shigella boydii, Escherichia alkalescens, Escherichia hermanii, and Escherichia fergusonii. Increased O6-methylguanine-DNA and methylphosphotriester-DNA methyltransferase activities correlated with the induction of a 39-kDa protein recognized by monoclonal antibodies raised against the Escherichia coli Ada protein. Induced methyltransferase activities were similarly observed in Aerobacter aerogenes and Citrobacter intermedius, although no antigenically cross-reacting material was present. Weak induction of a 39-kDa protein immunologically related to the E. coli Ada protein occurred in Salmonella typhimurium. This protein encoded by the cloned S. typhimurium ada gene was shown to be an active methyltransferase which repaired O6-methylguanine and methylphosphotriesters in DNA as efficiently as did the E. coli Ada protein. However, the mehtyltransferase activity of the weakly induced 39-kDa protein in S. typhimurium was not detected, apparently because it was self-methylated and thus inactivated during the adaptive N-methyl-N-nitro-N-nitrosoguanidine pretreatment. In contrast, the E. coli ada gene on a low-copy-number plasmid was efficiently induced in S. typhimurium, and high methyltransferase activities were observed. We concluded that the inefficient induction of the adaptive response in S. typhimurium results from weak transcriptional activation of its ada gene by the self-methylated protein.