Amplified expression of the tag+ and alkA+ genes in Escherichia coli: identification of gene products and effects on alkylation resistance

Cellular heterogeneity in DNA alkylation repair increases population genetic plasticity

DNA repair mechanisms fulfil a dual role, as they are essential for cell survival and genome maintenance. Here, we studied how cells regulate the interplay between DNA repair and mutation. We focused on the adaptive response that increases the resistance of Escherichia coli cells to DNA alkylation damage. Combination of single-molecule imaging and microfluidic-based single-cell microscopy showed that noise in the gene activation timing of the master regulator Ada is accurately propagated to generate a distinct subpopulation of cells in which all proteins of the adaptive response are essentially absent. Whereas genetic deletion of these proteins causes extreme sensitivity to alkylation stress, a temporary lack of expression is tolerated and increases genetic plasticity of the whole population. We demonstrated this by monitoring the dynamics of nascent DNA mismatches during alkylation stress as well as the frequency of fixed mutations that are generated by the distinct subpopulations of the adaptive response. We propose that stochastic modulation of DNA repair capacity by the adaptive response creates a viable hypermutable subpopulation of cells that acts as a source of genetic diversity in a clonal population.

Occurrence and repair of alkylating stress in the intracellular pathogen Brucella abortus

It is assumed that intracellular pathogenic bacteria have to cope with DNA alkylating stress within host cells. Here we use single-cell reporter systems to show that the pathogen Brucella abortus does encounter alkylating stress during the first hours of macrophage infection. Genes encoding direct repair and base-excision repair pathways are required by B. abortus to face this stress in vitro and in a mouse infection model. Among these genes, ogt is found to be under the control of the conserved cell-cycle transcription factor GcrA. Our results highlight that the control of DNA repair in B. abortus displays distinct features that are not present in model organisms such as Escherichia coli.

It is assumed that intracellular pathogenic bacteria must cope with DNA alkylating stress within host cells. Here, Poncin et al. show that the pathogen Brucella abortus does encounter alkylating stress within macrophages, and shed light into the pathways required for DNA repair in this organism.

Characterization of Trypanosoma cruzi MutY DNA glycosylase ortholog and its role in oxidative stress response

Trypanosoma cruzi is a protozoan parasite and the causative agent of Chagas disease. Like most living organisms, it is susceptible to oxidative stress, and must adapt to distinct environments. Hence, DNA repair is essential for its survival and the persistence of infection. Therefore, we studied whether T. cruzi has a homolog counterpart of the MutY enzyme (TcMYH), important in the DNA Base Excision Repair (BER) mechanism. Analysis of T. cruzi genome database showed that this parasite has a putative MutY DNA glycosylase sequence. We performed heterologous complementation assays using this genomic sequence. TcMYH complemented the Escherichia coli MutY- strain, reducing the mutation rate to a level similar to wild type. In in vitro assays, TcMYH was able to remove an adenine that was opposite to 8-oxoguanine. We have also constructed a T. cruzi lineage that overexpresses MYH. Although in standard conditions this lineage has similar growth to control cells, the overexpressor is more sensitive to hydrogen peroxide and glucose oxidase than the control, probably due to accumulation of AP sites in its DNA. Localization experiments with GFP-fused TcMYH showed this enzyme is present in both nucleus and mitochondrion. QPCR and MtOX results reinforce the presence and function of TcMYH in these two organelles. Our data suggest T. cruzi has a functional MYH DNA glycosylase, which participates in nuclear and mitochondrial DNA Base Excision Repair.

Chromosomal islands of Streptococcus pyogenes and related streptococci: molecular switches for survival and virulence

Streptococcus pyogenes is a significant pathogen of humans, annually causing over 700,000,000 infections and 500,000 deaths. Virulence in S. pyogenes is closely linked to mobile genetic elements like phages and chromosomal islands (CI). S. pyogenes phage-like chromosomal islands (SpyCI) confer a complex mutator phenotype on their host. SpyCI integrate into the 5′ end of DNA mismatch repair (MMR) gene mutL, which also disrupts downstream operon genes lmrP, ruvA, and tag. During early logarithmic growth, SpyCI excise from the bacterial chromosome and replicate as episomes, relieving the mutator phenotype. As growth slows and the cells enter stationary phase, SpyCI reintegrate into the chromosome, again silencing the MMR operon. This system creates a unique growth-dependent and reversible mutator phenotype. Additional CI using the identical attachment site in mutL have been identified in related species, including Streptococcus dysgalactiae subsp. equisimilis, Streptococcus anginosus, Streptococcus intermedius, Streptococcus parauberis, and Streptococcus canis. These CI have small genomes, which range from 13 to 20 kB, conserved integrase and DNA replication genes, and no identifiable genes encoding capsid proteins. SpyCI may employ a helper phage for packaging and dissemination in a fashion similar to the Staphylococcus aureus pathogenicity islands (SaPI). Outside of the core replication and integration genes, SpyCI and related CI show considerable diversity with the presence of many indels that may contribute to the host cell phenotype or fitness. SpyCI are a subset of a larger family of streptococcal CI who potentially regulate the expression of other host genes. The biological and phylogenetic analysis of streptococcal chromosomal islands provides important clues as to how these chromosomal islands help S. pyogenes and other streptococcal species persist in human populations in spite of antibiotic therapy and immune challenges.

Balancing repair and tolerance of DNA damage caused by alkylating agents

Alkylating agents constitute a major class of frontline chemotherapeutic drugs that inflict cytotoxic DNA damage as their main mode of action, in addition to collateral mutagenic damage. Numerous cellular pathways, including direct DNA damage reversal, base excision repair (BER) and mismatch repair (MMR), respond to alkylation damage to defend against alkylation-induced cell death or mutation. However, maintaining a proper balance of activity both within and between these pathways is crucial for a favourable response of an organism to alkylating agents. Furthermore, the response of an individual to alkylating agents can vary considerably from tissue to tissue and from person to person, pointing to genetic and epigenetic mechanisms that modulate alkylating agent toxicity.

Base excision repair and its role in maintaining genome stability

For all living organisms, genome stability is important, but is also under constant threat because various environmental and endogenous damaging agents can modify the structural properties of DNA bases. As a defense, organisms have developed different DNA repair pathways. Base excision repair (BER) is the predominant pathway for coping with a broad range of small lesions resulting from oxidation, alkylation, and deamination, which modify individual bases without large effect on the double helix structure. As, in mammalian cells, this damage is estimated to account daily for 10(4) events per cell, the need for BER pathways is unquestionable. The damage-specific removal is carried out by a considerable group of enzymes, designated as DNA glycosylases. Each DNA glycosylase has its unique specificity and many of them are ubiquitous in microorganisms, mammals, and plants. Here, we review the importance of the BER pathway and we focus on the different roles of DNA glycosylases in various organisms.

Involvement of Escherichia coli DNA polymerase IV in tolerance of cytotoxic alkylating DNA lesions in vivo

Escherichia coli PolIV, a DNA polymerase capable of catalyzing synthesis past replication-blocking DNA lesions, belongs to the most ubiquitous branch of Y-family DNA polymerases. The goal of this study is to identify spontaneous DNA damage that is bypassed specifically and accurately by PolIV in vivo. We increased the amount of spontaneous DNA lesions using mutants deficient for different DNA repair pathways and measured mutation frequency in PolIV-proficient and -deficient backgrounds. We found that PolIV performs an error-free bypass of DNA damage that accumulates in the alkA tag genetic background. This result indicates that PolIV is involved in the error-free bypass of cytotoxic alkylating DNA lesions. When the amount of cytotoxic alkylating DNA lesions is increased by the treatment with chemical alkylating agents, PolIV is required for survival in an alkA tag-proficient genetic background as well. Our study, together with the reported involvement of the mammalian PolIV homolog, Polkappa, in similar activity, indicates that Y-family DNA polymerases from the DinB branch can be added to the list of evolutionarily conserved molecular mechanisms that counteract cytotoxic effects of DNA alkylation. This activity is of major biological relevance because alkylating agents are continuously produced endogenously in all living cells and are also present in the environment.

A new protein superfamily includes two novel 3-methyladenine DNA glycosylases from Bacillus cereus, AlkC and AlkD

Soil bacteria are heavily exposed to environmental methylating agents such as methylchloride and may have special requirements for repair of alkylation damage on DNA. We have used functional complementation of an Escherichia coli tag alkA mutant to screen for 3-methyladenine DNA glycosylase genes in genomic libraries of the soil bacterium Bacillus cereus. Three genes were recovered: alkC, alkD and alkE. The amino acid sequence of AlkE is homologous to the E. coli AlkA sequence. AlkC and AlkD represent novel proteins without sequence similarity to any protein of known function. However, iterative and indirect sequence similarity searches revealed that AlkC and AlkD are distant homologues of each other within a new protein superfamily that is ubiquitous in the prokaryotic kingdom. Homologues of AlkC and AlkD were also identified in the amoebas Entamoeba histolytica and Dictyostelium discoideum, but no other eukaryotic counterparts of the superfamily were found. The alkC and alkD genes were expressed in E. coli and the proteins were purified to homogeneity. Both proteins were found to be specific for removal of N-alkylated bases, and showed no activity on oxidized or deaminated base lesions in DNA. B. cereus AlkC and AlkD thus define novel families of alkylbase DNA glycosylases within a new protein superfamily.

Human and bacterial oxidative demethylases repair alkylation damage in both RNA and DNA

Repair of DNA damage is essential for maintaining genome integrity, and repair deficiencies in mammals are associated with cancer, neurological disease and developmental defects. Alkylation damage in DNA is repaired by at least three different mechanisms, including damage reversal by oxidative demethylation of 1-methyladenine and 3-methylcytosine by Escherichia coli AlkB. By contrast, little is known about consequences and cellular handling of alkylation damage to RNA. Here we show that two human AlkB homologues, hABH2 and hABH3, also are oxidative DNA demethylases and that AlkB and hABH3, but not hABH2, also repair RNA. Whereas AlkB and hABH3 prefer single-stranded nucleic acids, hABH2 acts more efficiently on double-stranded DNA. In addition, AlkB and hABH3 expressed in E. coli reactivate methylated RNA bacteriophage MS2 in vivo, illustrating the biological relevance of this repair activity and establishing RNA repair as a potentially important defence mechanism in living cells. The different catalytic properties and the different subnuclear localization patterns shown by the human homologues indicate that hABH2 and hABH3 have distinct roles in the cellular response to alkylation damage.

Sequence variation in the human uracil-DNA glycosylase (UNG) gene

Spontaneous deamination of cytosine results in a premutagenic G:U mismatch that may result in a GC-->AT transition during replication. The human UNG-gene encodes the major uracil-DNA glycosylase (UDG or UNG) which releases uracil from DNA, thus, initiating base excision repair to restore the correct DNA sequence. Bacterial and yeast mutants lacking the homologous UDG exhibit elevated spontaneous mutation frequencies. Hence, mutations in the human UNG gene could presumably result in a mutator phenotype. We screened all seven exons including exon-intron boundaries, both promoters, and one intron of the UNG gene and identified considerable sequence variation in cell lines derived from normal fibroblasts and tumour tissue. None of the sequence variants was accompanied by significantly reduced UDG activity. In the UNG gene from 62 sources, we identified 12 different variant alleles, with allele frequencies ranging from 0.01 to 0.23. We identified one variant allele per 3.8kb in non-coding regions, but none in the coding region of the gene. In promoter B we identified four different variants. A substitution within an AP2 element was observed in tumour cell lines only and had an allele frequency of 0.10. Introduction of this substitution into chimaeric promoter-luciferase constructs affected transcription from the promoter. UDG-activity varied little in fibroblasts, but widely between tumour cell lines. This variation did not however correlate with the presence of any of the variant alleles. In conclusion, mutations affecting the function of human UNG gene are seemingly infrequent in human tumour cell lines.

Imbalanced base excision repair increases spontaneous mutation and alkylation sensitivity in Escherichia coli

Inappropriate expression of 3-methyladenine (3MeA) DNA glycosylases has been shown to have harmful effects on microbial and mammalian cells. To understand the underlying reasons for this phenomenon, we have determined how DNA glycosylase activity and substrate specificity modulate glycosylase effects in Escherichia coli. We compared the effects of two 3MeA DNA glycosylases with very different substrate ranges, namely, the Saccharomyces cerevisiae Mag1 and the E. coli Tag glycosylases. Both glycosylases increased spontaneous mutation, decreased cell viability, and sensitized E. coli to killing by the alkylating agent methyl methanesulfonate. However, Tag had much less harmful effects than Mag1. The difference between the two enzymes' effects may be accounted for by the fact that Tag almost exclusively excises 3MeA lesions, whereas Mag1 excises a broad range of alkylated and other purines. We infer that the DNA lesions responsible for changes in spontaneous mutation, viability, and alkylation sensitivity are abasic sites and secondary lesions resulting from processing abasic sites via the base excision repair pathway.

3-methyladenine DNA glycosylases: structure, function, and biological importance

The genome continuously suffers damage due to its reactivity with chemical and physical agents. Finding such damage in genomes (that can be several million to several billion nucleotide base pairs in size) is a seemingly daunting task. 3-Methyladenine DNA glycosylases can initiate the base excision repair (BER) of an extraordinarily wide range of substrate bases. The advantage of such broad substrate recognition is that these enzymes provide resistance to a wide variety of DNA damaging agents; however, under certain circumstances, the eclectic nature of these enzymes can confer some biological disadvantages. Solving the X-ray crystal structures of two 3-methyladenine DNA glycosylases, and creating cells and animals altered for this activity, contributes to our understanding of their enzyme mechanism and how such enzymes influence the biological response of organisms to several different types of DNA damage.

Generation of a strong mutator phenotype in yeast by imbalanced base excision repair

Increased spontaneous mutation is associated with increased cancer risk. Here, by using a model system, we show that spontaneous mutation can be increased several hundred-fold by a simple imbalance between the first two enzymes involved in DNA base excision repair. The Saccharomyces cerevisiae MAG1 3-methyladenine (3MeA) DNA glycosylase, when expressed at high levels relative to the apurinic/apyrimidinic endonuclease, increases spontaneous mutation by up to approximately 600-fold in S. cerevisiae and approximately 200-fold in Escherichia coli. Genetic evidence suggests that, in yeast, the increased spontaneous mutation requires the generation of abasic sites and the processing of these sites by the REV1/REV3/REV7 lesion bypass pathway. Comparison of the mutator activity produced by Mag1, which has a broad substrate range, with that produced by the E. coli Tag 3MeA DNA glycosylase, which has a narrow substrate range, indicates that the removal of endogenously produced 3MeA is unlikely to be responsible for the mutator effect of Mag1. Finally, the human AAG 3-MeA DNA glycosylase also can produce a small (approximately 2-fold) but statistically significant increase in spontaneous mutation, a result which could have important implications for carcinogenesis.

Release of normal bases from intact DNA by a native DNA repair enzyme

Base excision repair is initiated by DNA glycosylases removing inappropriate bases from DNA. One group of these enzymes, comprising 3-methyladenine DNA glycosylase II (AlkA) from Escherichia coli and related enzymes from other organisms, has been found to have an unusual broad specificity towards quite different base structures. We tested whether such enzymes might also be capable of removing normal base residues from DNA. The native enzymes from E.coli, Saccharomyces cerevisiae and human cells promoted release of intact guanines with significant frequencies, and further analysis of AlkA showed that all the normal bases can be removed. Transformation of E. coli with plasmids expressing different levels of AlkA produced an increased spontaneous mutation frequency correlated with the expression levels, indicating that excision of normal bases occurs at biologically significant rates. We propose that the broad specificity 3-methyladenine DNA glycosylases represent a general type of repair enzyme 'pulling' bases in DNA largely at random, without much preference for a specific structure. The specificity for release of damaged bases occurs because base structure alterations cause instability of the base-sugar bonds. Damaged bases are therefore released more readily than normal bases once the bond activation energy is reduced further by the enzyme. Qualitatively, the model correlates quite well with the relative rate of excision observed for most, if not all, of the substrates described for AlkA and analogues.

Different efficiencies of the Tag and AlkA DNA glycosylases from Escherichia coli in the removal of 3-methyladenine from single-stranded DNA

Escherichia coli possesses two different DNA repair glycosylases, Tag and AlkA, which have similar ability to remove the alkylation product 3-methyladenine from double-stranded DNA. In this study we show that these enzymes have quite different activities for the excision of 3-methyladenine from single-stranded DNA, AlkA being 10-20 times more efficient than Tag. We propose that AlkA and perhaps other glycosylases as well may have an important role in the excision of base damage from single-stranded regions transiently formed in DNA during transcription and replication.

Effect of overexpression of E. coli 3-methyladenine-DNA glycosylase I (Tag) on survival and mutation induction in Salmonella typhimurium

Salmonella typhimurium, compared to Escherichia coli, is deficient in an inducible glycosylase activity harbouring only constitutive glycosylase functions. 3-Methyladenine-DNA glycosylase I encoded by the E. coli tag gene is a constitutively expressed repair enzyme that primarily removes N3-methyladenine but also N3-methylguanine from DNA by glycosylic cleavage in the first step of the base excision repair. In order to investigate in vivo effect of the overexpressed glycosylase I activity on survival capacity and mutation induction in S. typhimurium, and thereby elucidate the significance of both 3-methylpurines in cellular sensitivity to methylating agents (e.g., DMS), we transformed four his- S. typhimurium strains with the plasmid pCY5 carrying the E. coli tag gene under the control of the lac promoter. Although the 3-methyladenine-DNA glycosylase activity in cells carrying pCY5 was only 10-fold higher on exposure to IPTG compared to the TA1535 control strain carrying pUC8, the overexpression of the Tag protein completely suppressed deficiency in an inducible glycosylase activity, rendering cells resistance to toxic effects of DMS. The suppression was not influenced by the nucleotide excision repair pathway since there was no difference in recovered survival among NER-proficient and NER-deficient strains. The yield of mutation induction in the reversion assay was decreased to the level of spontaneous (his-->his+) revertant colonies showing that in the overall population in overexpressed conditions in vivo 3-methyl-guanine, in addition to 3-methyladenine, must have been removed from DNA by the E. coli Tag protein and therefore accounts for the second most important cytotoxic lesion.

Cloning and characterization of a cDNA encoding a 3-methyladenine DNA glycosylase from the fission yeast Schizosaccharomyces pombe

We have begun to develop the fission yeast, Schizosaccharomyces pombe, as a eukaryotic model for cellular defenses against alkylating agents. Here we describe the cloning and characterization of a cDNA, designated mag1, encoding a S. pombe 3-methyladenine (3MeA) DNA glycosylase. 3MeA DNA glycosylases in Escherichia coli are encoded by alkA and tag. S. pombe mag1 was cloned by its ability to reverse the alkylation-sensitive phenotype of an alkA tag E. coli double mutant. The expression of S. pombe mag1 in E. coli confers partial resistance to alkylating agents that produce methyl, ethyl and propyl lesions, and Mag1 production produces 3MeA DNA glycosylase activity. In contrast to the E. coli alkA and Saccharomyces cerevisiae MAG genes, expression of S. pombe mag1 was not appreciably induced by alkylating agents. The mag1 cDNA encodes a protein of 228 amino acids (aa) that shares similarity with 3MeA DNA glycosylases from E. coli (AlkA), Bacillus subtilis (BsAlkA) and S. cerevisiae (MAG). A consensus sequence of 9 aa common to these microbial 3MeA DNA glycosylases is discussed.

The Ada protein acts as both a positive and a negative modulator of Escherichia coli's response to methylating agents

The adaptive response of Escherichia coli protects the cells against the toxic and mutagenic effects of certain alkylating agents. The major effector molecule regulating this response is the 39-kDa Ada protein, which functions as both a DNA repair protein and a transcriptional activator. Ada removes methyl groups from phosphotriester and O6-methylguanine lesions in DNA, irreversibly transferring them to cysteine residues at positions 69 and 321, respectively. When methylated at Cys-69, Ada is converted into a potent activator of ada and alkA transcription and binds to a sequence (Ada box) present in both promoters. We have found that physiologically relevant higher concentrations of unmethylated Ada are able to inhibit the activation of ada transcription by methylated Ada, both in vitro and in vivo. In contrast, the same concentrations of unmethylated Ada do not inhibit the activation of alkA transcription by methylated Ada, either in vitro or in vivo. Deletion of the carboxyl-terminal 67 amino acids of Ada abolished the ability of the unmethylated form of the protein to inhibit activation of ada transcription but not the ability of the methylated form to activate ada or alkA transcription. Our results suggest that the Ada protein plays a pivotal role in the negative modulation of its own synthesis and therefore in the down-regulation of the adaptive response. Elements present in the carboxyl terminus of Ada appear to be necessary for this negative regulatory function.

Functions of the gene products of Escherichia coli

A list of currently identified gene products of Escherichia coli is given, together with a bibliography that provides pointers to the literature on each gene product. A scheme to categorize cellular functions is used to classify the gene products of E. coli so far identified. A count shows that the numbers of genes concerned with small-molecule metabolism are on the same order as the numbers concerned with macromolecule biosynthesis and degradation. One large category is the category of tRNAs and their synthetases. Another is the category of transport elements. The categories of cell structure and cellular processes other than metabolism are smaller. Other subjects discussed are the occurrence in the E. coli genome of redundant pairs and groups of genes of identical or closely similar function, as well as variation in the degree of density of genetic information in different parts of the genome.

Mechanism of toxicity of 3-methyladenine for bacteriophage T7

Treatment of bacteriophage T7 with methyl methanesulfonate perturbed phage-specific genetic expression in both repair-proficient and repair-deficient Escherichia coli cells. In wild-type cells (AB1157), the time course of protein synthesis was slowed down but an entire complement of phage proteins was synthesized. In cells (BK2114, tag-) unable to repair 3-methyladenine, the toxic lesion produced by methyl methanesulfonate, alkylated phage produced only early (class I) proteins. These results suggested that late transcription was inhibited in infected tag- cells. These cells were shown to contain a significant amount of active T7 RNA polymerase, a class I protein. Thus, the cause of inhibition appeared to be the inability of T7 RNA polymerase to use unrepaired DNA as template. In vitro transcription assays with alkylated T7 DNA as template supported this proposal. T7 RNA polymerase proved to be very sensitive to the presence of alkylation lesions. In addition, the phage enzyme was much more sensitive to these lesions than was its bacterial counterpart, E. coli RNA polymerase. These results suggest that 3-methyladenine exerts its toxic action, in the T7 system, at the level of transcription by T7 RNA polymerase. To further characterize the reduced activity of the T7 enzyme, an in vitro transcription assay using linearized plasmid DNA with one T7 promoter was devised. Gel electrophoresis revealed that only one transcript of well-defined length was synthesized by T7 RNA polymerase on this template. Alkylation of the template did not alter the size of the transcript produced. Simultaneous measurement of chain initiation and chain elongation confirmed this result by showing that both steps were reduced to the same extent by alkylation of template DNA. Thus T7 RNA polymerase does not appear to be blocked by 3-methyladenine. Rather the lesion must hinder translocation of T7 RNA polymerase along the DNA template during chain elongation.

Bacillus subtilis alkA gene encoding inducible 3-methyladenine DNA glycosylase is adjacent to the ada operon

In Bacillus subtilis, the adaptive response to DNA alkylation depends on the ada operon, which consists of the adaA and adaB genes, which encode methylphosphotriester DNA methyltransferase (AdaA protein) and O6-methylguanine DNA methyltransferase (AdaB protein), respectively. A structural gene (alkA) that encodes 3-methyladenine DNA glycosylase was found upstream of the ada operon, but in the opposite orientation. This cluster of genes was mapped at about 235 kb from the SfiI recognition site near the origin of replication in the physical map of the B. subtilis chromosome. Disruption of the alkA gene sensitized cells to N-propyl-N'-nitro-N-nitrosoguanidine, while its overproduction rendered cells highly resistant to N-propyl-N'-nitro-N-nitrosoguanidine, indicating that lethal DNA damage produced by bulky alkylating agents was effectively counteracted by AlkA glycosylase. Transcription of the alkA gene was induced by treating adaA+ cells with methylating agents concurrent with transcription of the ada operon. This was accomplished by using methylated AdaA protein bound to a 30-bp segment in the middle of the 100-bp sequence between the transcriptional start sites of the alkA gene and ada operon. Thus, in this organism, the adaptive response to DNA alkylation is achieved by autologous activation of a divergent regulon composed of the genes for a DNA glycosylase and two species of DNA alkyltransferase.

Excision of 3-methylguanine from alkylated DNA by 3-methyladenine DNA glycosylase I of Escherichia coli

Escherichia coli has two DNA glycosylases for repair of DNA damage caused by simple alkylating agents. The inducible AlkA DNA glycosylase (3-methyladenine [m3A] DNA glycosylase II) removes several different alkylated bases including m3A and 3-methylguanine (m3G) from DNA, whereas the constitutively expressed Tag enzyme (m3A DNA glycosylase I) has appeared to be specific for excision of m3A. In this communication we have reexamined the substrate specificity of Tag by using synthetic DNA rich in GC base pairs to facilitate detection of any possible methyl-G removal. In such DNA alkylated with [3H]dimethyl sulphate, we found that m3G was excised from double-stranded DNA by both glycosylases, although more efficiently by AlkA than by Tag. This was further confirmed using both N-[3H]methyl-N-nitrosourea- and [3H]dimethyl sulphate-treated native DNA, from which Tag excised m3G with an efficiency that was about 70 times lower than for AlkA. These results can explain the previous observation that high levels of Tag expression will suppress the alkylation sensitivity of alkA mutant cells, further implying that m3G is formed in quantity sufficient to represent an important cytotoxic lesion if left unrepaired in cells exposed to alkylating agents.

Repair of cytotoxic lesions induced by N-methyl-N'-nitro-N-nitrosoguanidine in Salmonella typhimurium and Escherichia coli

The role of nucleotide excision repair and 3-methyladenine DNA glycosylases in removing cytotoxic lesions induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) in Salmonella typhimurium and Escherichia coli cells was examined. Compared to the E. coli wild-type strain, the S. typhimurium wild-type strain was more sensitive to the same dose of MNNG. Nucleotide excision repair in both bacterial species does not contribute significantly to the survival after MNNG treatment, indicating that the observed differences in survival between S. typhimurium and E. coli should be attributed to DNA-repair systems other than nucleotide excision repair. The survival of the E. coli alkA mutant strain is seriously affected by the lack of 3-methyladenine DNA glycosylase II, accentuating the importance of this DNA-repair enzyme in protecting E. coli cells against the lethal effects of methylating agents. Following indications from our experiments, the existence of an alkA gene analogue in S. typhimurium has been questioned. Dot-blot hybridisation, using the E. coli alkA gene as a probe, was performed, and such a nucleotide sequence was not detected on S. typhimurium genomic DNA. The existence of constitutive 3-methyladenine DNA glycosylase, analogous to the E. coli Tag gene product in S. typhimurium cells, suggested by the results is discussed.

Serratia marcescens rpr gene sensitizes Escherichia coli wild-type, xth, and nfo strains to methyl methanesulphonate

It is reported here that the rpr DNA repair gene of Serratia marcescens does not complement an Escherichia coli xth nfo AP endonuclease mutation for resistance to methyl methanesulphonate (MMS). Rather, rpr sensitized Escherichia coli wild-type, xth, and nfo strains to MMS. Also, it was found that rpr could not complement a triple tag alkA recA mutation in E. coli, indicating that there are limits to rpr complementing capabilities. It was determined that rpr gene dosage was not a factor in recA complementation. MMS sensitization of an E. coli wild-type strain, however, was directly related to rpr copy number. These data indicate that Rpr does not have an associated AP endonuclease activity, and that it is incapable of substituting for Tag I, Tag II, and RecA in a tag alkA recA background.

Evidence for unique DNA repair activity encoded by a cloned Serratia marcescens gene: suppression of Escherichia coli mutations that reduce repair of alkylated DNA

A recombinant plasmid containing a Serratia marcescens DNA repair gene has been analyzed biochemically and genetically in Escherichia coli mutants deficient for repair of alkylated DNA. The cloned gene suppressed sensitivity to methyl methanesulfonate of an E. coli strain deficient in 3-methyladenine DNA glycosylases I and II (i.e., E. coli tag alkA) and two different E. coli recA mutants. Attempts to suppress the methyl methanesulfonate sensitivity of the E. coli recA mutant by using the cloned E. coli tag and alkA genes were not successful. Southern blot analysis did not reveal any homology between the S. marcescens gene and various known E. coli DNA repair genes. Biochemical analysis with the S. marcescens gene showed that the encoded DNA repair protein liberated 3-methyladenine from alkylated DNA, indicating that the DNA repair molecular is an S. marcescens 3-methyladenine DNA glycosylase. The ability to suppress both types of E. coli DNA repair mutations, however, suggests that the S. marcescens gene is a unique bacterial DNA repair gene.

Molecular cloning and characterization of a genetic region from Serratia marcescens involved in DNA repair

We report here the molecular isolation of a DNA fragment which encodes Tag-like activity from the Gram-negative bacterium Serratia marcescens. A recombinant plasmid encoding Tag-like activity was isolated from a S. marcescens plasmid gene library by complementation of an Escherichia coli tag mutant, which is deficient in 3-methyladenine DNA glycosylase I. The clone complements E. coli tag, recA, alkA, but not alkB, mutants for resistance to the DNA-damaging agent methyl methanesulphonate (MMS). The coding region of the Tag activity, initially isolated on a 6.5kb BamHI fragment, was defined to a 1.8kb BglII-SmaI fragment. Labelling of plasmid-encoded proteins using maxicells revealed that the 1.8kb fragment encodes two proteins of molecular weights 42,000 and 16,000. Data presented here suggest that the cloned fragment encodes a DNA repair protein(s) that has similar activity to the 3-methyladenine DNA glycosylase I of E. coli.

Alteration of the carboxyl-terminal domain of Ada protein influences its inducibility, specificity, and strength as a transcriptional activator

The ada gene of Escherichia coli K-12 encodes the regulatory protein for the adaptive response to alkylating agents. A set of plasmids carrying ordered deletions from the 3' end of the ada gene were isolated and characterized. These ada deletions encode fusion proteins that derive their amino termini from ada and their carboxyl termini from the downstream vector sequence that occurs before an in-frame stop codon. Several of these ada deletions encode Ada derivatives that constitutively activate ada transcription to very high levels. A second class of ada deletions encode Ada derivatives that are dominant inhibitors of the inducible transcription of ada but are inducible activators of alkA transcription. In addition, we found that two Ada derivatives containing the same ada sequences but fused to different vector-derived tails have strikingly different properties. One Ada derivative constitutively activates both ada and alkA expression to very high levels. In contrast, the other Ada derivative is an inducible activator of ada expression, like the wild-type Ada protein, but is not an inducible activator of alkA transcription. Our data suggest that the carboxyl terminus of the Ada protein plays a key role in modulating the ability of the Ada protein to function as a transcriptional activator.

Purification and characterization of 3-methyladenine DNA glycosylase I from Escherichia coli

We have purified 3-methyladenine DNA glycosylase I from Escherichia coli to apparent physical homogeneity. The enzyme preparation produced a single band of Mr 22,500 upon sodium dodecyl sulphate/polyacrylamide gel electrophoresis in good agreement with the molecular weight deduced from the nucleotide sequence of the tag gene (Steinum, A.-L. and Seeberg, E. (1986) Nucl. Acids Res. 14, 3763-3772). HPLC confirmed that the only detectable alkylation product released from (3H)dimethyl sulphate treated DNA was 3-methyladenine. The DNA glycosylase activity showed a broad pH optimum between 6 and 8.5, and no activity below pH 5 and above pH 10. MgSO4, CaCl2 and MnCl2 stimulated enzyme activity, whereas ZnSO4 and FeCl3 inhibited the enzyme at 2 mM concentration. The enzyme was stimulated by caffeine, adenine and 3-methylguanine, and inhibited by p-hydroxymercuribenzoate, N-ethylmaleimide and 3-methyladenine. The enzyme showed no detectable endonuclease activity on native, depurinated or alkylated plasmid DNA. However, apurinic sites were introduced in alkylated DNA as judged from the strand breaks formed by mixtures of the tag enzyme and the bacteriophage T4 denV enzyme which has apurinic/apyrimidinic endonuclease activity. It was calculated that wild-type E. coli contains approximately 200 molecules per cell of 3-methyladenine DNA glycosylase I.