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

Replication Studies of Alkyl Phosphotriester Lesions in Human Cells

Alkyl phosphotriester (alkyl-PTE) lesions in DNA are shown to be poorly repaired; however, little is known about how these lesions impact DNA replication in human cells. Here, we investigated how the SP and RP diastereomers of four alkyl-PTE lesions (alkyl = Me, Et, nPr, or nBu) at the TT site perturb DNA replication in HEK293T cells. We found that these lesions moderately impede DNA replication and that their replicative bypass is accurate. Moreover, CRISPR-Cas9-mediated depletion of Pol η or Pol ζ resulted in significantly attenuated bypass efficiencies for both diastereomers of nPr- and nBu-PTE adducts, and the SP diastereomer of Et-PTE. Diminished bypass efficiencies were also detected for the Rp diastereomer of nPr- and nBu-PTE lesions upon ablation of Pol κ. Together, our study uncovered the impact of the alkyl-PTE lesions on DNA replication in human cells and revealed the roles of individual translesion synthesis DNA polymerases in bypassing these lesions.

Widespread prevalence of a methylation-dependent switch to activate an essential DNA damage response in bacteria

DNA methylation plays central roles in diverse cellular processes, ranging from error-correction during replication to regulation of bacterial defense mechanisms. Nevertheless, certain aberrant methylation modifications can have lethal consequences. The mechanisms by which bacteria detect and respond to such damage remain incompletely understood. Here, we discover a highly conserved but previously uncharacterized transcription factor (Cada2), which orchestrates a methylation-dependent adaptive response in Caulobacter. This response operates independently of the SOS response, governs the expression of genes crucial for direct repair, and is essential for surviving methylation-induced damage. Our molecular investigation of Cada2 reveals a cysteine methylation-dependent posttranslational modification (PTM) and mode of action distinct from its Escherichia coli counterpart, a trait conserved across all bacteria harboring a Cada2-like homolog instead. Extending across the bacterial kingdom, our findings support the notion of divergence and coevolution of adaptive response transcription factors and their corresponding sequence-specific DNA motifs. Despite this diversity, the ubiquitous prevalence of adaptive response regulators underscores the significance of a transcriptional switch, mediated by methylation PTM, in driving a specific and essential bacterial DNA damage response.

Methyl DNA phosphate adduct formation in lung tumor tissue and adjacent normal tissue of lung cancer patients

The formation of methyl DNA adducts is a critical step in carcinogenesis initiated by the exposure to methylating carcinogens. Methyl DNA phosphate adducts, formed by methylation of the oxygen atoms of the DNA phosphate backbone, have been detected in animals treated with methylating carcinogens. However, detection of these adducts in human tissues has not been reported. We developed an ultrasensitive liquid chromatography-nanoelectrospray ionization-high resolution tandem mass spectrometry method for detecting methyl DNA phosphate adducts. Using 50 μg of human lung DNA, a limit of quantitation of two adducts/1010 nucleobases was achieved. Twenty-two structurally unique methyl DNA phosphate adducts were detected in human lung DNA. The adduct levels were measured in both tumor and adjacent normal tissues from 30 patients with lung cancer, including 13 current smokers and 17 current non-smokers, as confirmed by measurements of urinary cotinine and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol. Levels of total methyl DNA phosphate adducts in normal lung tissues were higher in smokers than non-smokers, with an average of 13 and 8 adducts/109 nucleobases, respectively. Methyl DNA phosphate adducts were also detected in lung tissues from untreated rats with steady-state levels of 5-7 adducts/109 nucleobases over a period of 70 weeks. This is the first study to report the detection of methyl DNA phosphate adducts in human lung tissues. The results provide new insights toward using these DNA adducts as potential biomarkers to study human exposure to environmental methylating carcinogens.

Ada protein- and sequence context-dependent mutagenesis of alkyl phosphotriester lesions in Escherichia coli cells

Alkyl phosphotriester (alkyl-PTE) lesions are frequently induced in DNA and are resistant to repair. Here, we synthesized and characterized methyl (Me)- and n-butyl (nBu)-PTEs in two diastereomeric configurations (S _p and R _p) at six different flanking dinucleotide sites, i.e. XT and TX (X = A, C, or G), and assessed how these lesions impact DNA replication in Escherichia coli cells. When single-stranded vectors contained an S _p-Me-PTE in the sequence contexts of 5'-AT-3', 5'-CT-3', or 5'-GT-3', DNA replication was highly efficient and the replication products for all three sequence contexts contained 85-90% AT and 5-10% TG. Thus, the replication outcome was largely independent of the identity of the 5' nucleotide adjacent to an S _p-Me-PTE. Furthermore, replication across these lesions was not dependent on the activities of DNA polymerases II, IV, or V; Ada, a protein involved in adaptive response and repair of S _p-Me-PTE in E. coli, however, was essential for the generation of the mutagenic products. Additionally, the R _p diastereomer of Me-PTEs at XT sites and both diastereomers of Me-PTEs at TX sites exhibited error-free replication bypass. Moreover, S _p-nBu-PTEs at XT sites did not strongly impede DNA replication, and other nBu-PTEs displayed moderate blockage effects, with none of them being mutagenic. Taken together, these findings provide in-depth understanding of how alkyl-PTE lesions are recognized by the DNA replication machinery in prokaryotic cells and reveal that Ada contributes to mutagenesis of S _p-Me-PTEs in E. coli.

Cytotoxic and mutagenic properties of alkyl phosphotriester lesions in Escherichia coli cells

Exposure to many endogenous and exogenous agents can give rise to DNA alkylation, which constitutes a major type of DNA damage. Among the DNA alkylation products, alkyl phosphotriesters have relatively high frequencies of occurrence and are resistant to repair in mammalian tissues. However, little is known about how these lesions affect the efficiency and fidelity of DNA replication in cells or how the replicative bypass of these lesions is modulated by translesion synthesis DNA polymerases. In this study, we synthesized oligodeoxyribonucleotides containing four pairs (S_p and R_p) of alkyl phosphotriester lesions at a defined site, and examined how these lesions are recognized by DNA replication machinery in Escherichia coli cells. We found that the S_p diastereomer of the alkyl phosphotriester lesions could be efficiently bypassed, whereas the R_p counterparts moderately blocked DNA replication. Moreover, the S_p-methyl phosphotriester induced TT→GT and TT→GC mutations at the flanking TT dinucleotide site, and the induction of these mutations required Ada protein, which is known to remove efficiently the methyl group from the S_p-methyl phosphotriester. Together, our study provided a comprehensive understanding about the recognition of alkyl phosphotriester lesions by DNA replication machinery in cells, and revealed for the first time the Ada-dependent induction of mutations at the S_p-methyl phosphotriester site.

Mass Spectrometric Quantitation of Pyridyloxobutyl DNA Phosphate Adducts in Rats Chronically Treated with N'-Nitrosonornicotine

The tobacco-specific carcinogens N'-nitrosonornicotine (NNN) and 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) require metabolic activation to exert their carcinogenicity. NNN and NNK are metabolized to the same reactive diazonium ions, which alkylate DNA forming pyridyloxobutyl (POB) DNA base and phosphate adducts. We have characterized the formation of both POB DNA base and phosphate adducts in NNK-treated rats and the formation of POB DNA base adducts in NNN-treated rats. However, POB DNA phosphate adducts in NNN-treated rats are still uncharacterized. In this study, we quantified the levels of POB DNA phosphate adducts in tissues of rats chronically treated with ( S)-NNN or ( R)-NNN for 10, 30, 50, and 70 weeks during a carcinogenicity study. The highest amounts of POB DNA phosphate adducts were observed in the esophagus of the ( S)-NNN-treated rats, with a maximum level of 5400 ± 317 fmol/mg DNA at 50 weeks. The abundance of POB DNA phosphate adducts in the esophagus was consistent with the results of the carcinogenicity study showing that the esophagus was the primary site of tumor formation from treatment with ( S)-NNN. Compared to the ( R)-NNN group, the levels of POB DNA phosphate adducts were higher in the oral mucosa, esophagus, and liver, while lower in the nasal mucosa of the ( S)-NNN-treated rats. Among 10 combinations of all isomers of POB DNA phosphate adducts, Ap(POB)C and combinations with thymidine predominated across all the rat tissues examined. In the primary target tissue, esophageal mucosa, Ap(POB)C accounted for ∼20% of total phosphate adducts in the ( S)-NNN treatment group throughout the 70 weeks, with levels ranging from 780 ± 194 to 1010 ± 700 fmol/mg DNA. The results of this study showed that POB DNA phosphate adducts were present in high levels and persisted in target tissues of rats chronically treated with ( S)- or ( R)-NNN. These results improve our understanding of DNA damage during NNN-induced carcinogenesis. The predominant POB DNA phosphate isomers observed, such as Ap(POB)C, may serve as biomarkers for monitoring chronic exposure of tobacco-specific nitrosamines in humans.

Methyl DNA Phosphate Adduct Formation in Rats Treated Chronically with 4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone and Enantiomers of Its Metabolite 4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanol

The tobacco-specific nitrosamine 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) is a powerful lung carcinogen in animal models and is considered a causative factor for lung cancer in tobacco users. NNK is stereoselectively and reversibly metabolized to 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL), which is also a lung carcinogen. Both NNK and NNAL undergo metabolic activation by α-hydroxylation on their methyl groups to form pyridyloxobutyl and pyridylhydroxybutyl DNA base and phosphate adducts, respectively. α-Hydroxylation also occurs on the α-methylene carbons of NNK and NNAL to produce methane diazohydroxide, which reacts with DNA to form methyl DNA base adducts. DNA adducts of NNK and NNAL are important in their mechanisms of carcinogenesis. In this study, we characterized and quantified methyl DNA phosphate adducts in the lung of rats treated with 5 ppm of NNK, (S)-NNAL, or (R)-NNAL in drinking water for 10, 30, 50, and 70 weeks, by using a novel liquid chromatography-nanoelectrospray ionization-high resolution tandem mass spectrometry method. A total of 23, 21, and 22 out of 32 possible methyl DNA phosphate adducts were detected in the lung tissues of rats treated with NNK, (S)-NNAL, and (R)-NNAL, respectively. Levels of the methyl DNA phosphate adducts were 2290-4510, 872-1120, and 763-1430 fmol/mg DNA, accounting for 15-38%, 8%, and 5-9% of the total measured DNA adducts in rats treated with NNK, (S)-NNAL, and (R)-NNAL, respectively. The methyl DNA phosphate adducts characterized in this study further enriched the diversity of DNA adducts formed by NNK and NNAL. These results provide important new data regarding NNK- and NNAL-derived DNA damage and new insights pertinent to future mechanistic and biomonitoring studies of NNK, NNAL, and other chemical methylating agents.

Genomic and Transcriptomic Analysis of Growth-Supporting Dehalogenation of Chlorinated Methanes in Methylobacterium

Bacterial adaptation to growth with toxic halogenated chemicals was explored in the context of methylotrophic metabolism of Methylobacterium extorquens, by comparing strains CM4 and DM4, which show robust growth with chloromethane and dichloromethane, respectively. Dehalogenation of chlorinated methanes initiates growth-supporting degradation, with intracellular release of protons and chloride ions in both cases. The core, variable and strain-specific genomes of strains CM4 and DM4 were defined by comparison with genomes of non-dechlorinating strains. In terms of gene content, adaptation toward dehalogenation appears limited, strains CM4 and DM4 sharing between 75 and 85% of their genome with other strains of M. extorquens. Transcript abundance in cultures of strain CM4 grown with chloromethane and of strain DM4 grown with dichloromethane was compared to growth with methanol as a reference C₁ growth substrate. Previously identified strain-specific dehalogenase-encoding genes were the most transcribed with chlorinated methanes, alongside other genes encoded by genomic islands (GEIs) and plasmids involved in growth with chlorinated compounds as carbon and energy source. None of the 163 genes shared by strains CM4 and DM4 but not by other strains of M. extorquens showed higher transcript abundance in cells grown with chlorinated methanes. Among the several thousand genes of the M. extorquens core genome, 12 genes were only differentially abundant in either strain CM4 or strain DM4. Of these, 2 genes of known function were detected, for the membrane-bound proton translocating pyrophosphatase HppA and the housekeeping molecular chaperone protein DegP. This indicates that the adaptive response common to chloromethane and dichloromethane is limited at the transcriptional level, and involves aspects of the general stress response as well as of a dehalogenation-specific response to intracellular hydrochloric acid production. Core genes only differentially abundant in either strain CM4 or strain DM4 total 13 and 58 CDS, respectively. Taken together, the obtained results suggest different transcriptional responses of chloromethane- and dichloromethane-degrading M. extorquens strains to dehalogenative metabolism, and substrate- and pathway-specific modes of growth optimization with chlorinated methanes.

Mycofumigation by the volatile organic compound-producing Fungus Muscodor albus induces bacterial cell death through DNA damage

Muscodor albus belongs to a genus of endophytic fungi that inhibit and kill other fungi, bacteria, and insects through production of a complex mixture of volatile organic compounds (VOCs). This process of mycofumigation has found commercial application for control of human and plant pathogens, but the mechanism of the VOC toxicity is unknown. Here, the mode of action of these volatiles was investigated through a series of genetic screens and biochemical assays. A single-gene knockout screen revealed high sensitivity for Escherichia coli lacking enzymes in the pathways of DNA repair, DNA metabolic process, and response to stress when exposed to the VOCs of M. albus. Furthermore, the sensitivity of knockouts involved in the repair of specific DNA alkyl adducts suggests that the VOCs may induce alkylation. Evidence of DNA damage suggests that these adducts lead to breaks during DNA replication or transcription if not properly repaired. Additional cytotoxicity profiling indicated that during VOC exposure, E. coli became filamentous and demonstrated an increase in cellular membrane fluidity. The volatile nature of the toxic compounds produced by M. albus and their broad range of inhibition make this fungus an attractive biological agent. Understanding the antimicrobial effects and the VOC mode of action will inform the utility and safety of potential mycofumigation applications for M. albus.

My journey to DNA repair

I completed my medical studies at the Karolinska Institute in Stockholm but have always been devoted to basic research. My longstanding interest is to understand fundamental DNA repair mechanisms in the fields of cancer therapy, inherited human genetic disorders and ancient DNA. I initially measured DNA decay, including rates of base loss and cytosine deamination. I have discovered several important DNA repair proteins and determined their mechanisms of action. The discovery of uracil-DNA glycosylase defined a new category of repair enzymes with each specialized for different types of DNA damage. The base excision repair pathway was first reconstituted with human proteins in my group. Cell-free analysis for mammalian nucleotide excision repair of DNA was also developed in my laboratory. I found multiple distinct DNA ligases in mammalian cells, and led the first genetic and biochemical work on DNA ligases I, III and IV. I discovered the mammalian exonucleases DNase III (TREX1) and IV (FEN1). Interestingly, expression of TREX1 was altered in some human autoimmune diseases. I also showed that the mutagenic DNA adduct O⁶-methylguanine (O⁶mG) is repaired without removing the guanine from DNA, identifying a surprising mechanism by which the methyl group is transferred to a residue in the repair protein itself. A further novel process of DNA repair discovered by my research group is the action of AlkB as an iron-dependent enzyme carrying out oxidative demethylation.

Identification of methylated proteins in the yeast small ribosomal subunit: a role for SPOUT methyltransferases in protein arginine methylation

We have characterized the posttranslational methylation of Rps2, Rps3, and Rps27a, three small ribosomal subunit proteins in the yeast Saccharomyces cerevisiae, using mass spectrometry and amino acid analysis. We found that Rps2 is substoichiometrically modified at arginine-10 by the Rmt1 methyltransferase. We demonstrated that Rps3 is stoichiometrically modified by ω-monomethylation at arginine-146 by mass spectrometric and site-directed mutagenic analyses. Substitution of alanine for arginine at position 146 is associated with slow cell growth, suggesting that the amino acid identity at this site may influence ribosomal function and/or biogenesis. Analysis of the three-dimensional structure of Rps3 in S. cerevisiae shows that arginine-146 makes contacts with the small subunit rRNA. Screening of deletion mutants encoding potential yeast methyltransferases revealed that the loss of the YOR021C gene results in the absence of methylation of Rps3. We demonstrated that recombinant Yor021c catalyzes ω-monomethylarginine formation when incubated with S-adenosylmethionine and hypomethylated ribosomes prepared from a YOR021C deletion strain. Interestingly, Yor021c belongs to the family of SPOUT methyltransferases that, to date, have only been shown to modify RNA substrates. Our findings suggest a wider role for SPOUT methyltransferases in nature. Finally, we have demonstrated the presence of a stoichiometrically methylated cysteine residue at position 39 of Rps27a in a zinc-cysteine cluster. The discovery of these three novel sites of protein modification within the small ribosomal subunit will now allow for an analysis of their functional roles in translation and possibly other cellular processes.

Molecular mechanisms of the whole DNA repair system: a comparison of bacterial and eukaryotic systems

DNA is subjected to many endogenous and exogenous damages. All organisms have developed a complex network of DNA repair mechanisms. A variety of different DNA repair pathways have been reported: direct reversal, base excision repair, nucleotide excision repair, mismatch repair, and recombination repair pathways. Recent studies of the fundamental mechanisms for DNA repair processes have revealed a complexity beyond that initially expected, with inter- and intrapathway complementation as well as functional interactions between proteins involved in repair pathways. In this paper we give a broad overview of the whole DNA repair system and focus on the molecular basis of the repair machineries, particularly in Thermus thermophilus HB8.

Systems based mapping demonstrates that recovery from alkylation damage requires DNA repair, RNA processing, and translation associated networks

The identification of cellular responses to damage can promote mechanistic insight into stress signalling. We have screened a library of 3968 Escherichia coli gene-deletion mutants to identify 99 gene products that modulate the toxicity of the alkylating agent methyl methanesulfonate (MMS). We have developed an ontology mapping approach to identify functional categories over-represented with MMS-toxicity modulating proteins and demonstrate that, in addition to DNA re-synthesis (replication, recombination, and repair), proteins involved in mRNA processing and translation influence viability after MMS damage. We have also mapped our MMS-toxicity modulating proteins onto an E. coli protein interactome and identified a sub-network consisting of 32 proteins functioning in DNA repair, mRNA processing, and translation. Clustering coefficient analysis identified seven highly connected MMS-toxicity modulating proteins associated with translation and mRNA processing, with the high connectivity suggestive of a coordinated response. Corresponding results from reporter assays support the idea that the SOS response is influenced by activities associated with the mRNA-translation interface.

Human nucleotide excision repair efficiently removes chromium-DNA phosphate adducts and protects cells against chromate toxicity

Intracellular reduction of carcinogenic Cr(VI) leads to the extensive formation of Cr(III)-DNA phosphate adducts. Repair mechanisms for chromium and other DNA phosphate-based adducts are currently unknown in human cells. We found that nucleotide excision repair (NER)-proficient human cells rapidly removed chromium-DNA adducts, with an average t((1/2)) of 7.1 h, whereas NER-deficient XP-A, XP-C, and XP-F cells were severely compromised in their ability to repair chromium-DNA lesions. Activation of NER in Cr(VI)-treated human fibroblasts or lung epithelial H460 cells was manifested by XPC-dependent binding of the XPA protein to the nuclear matrix, which was also observed in UV light-treated (but not oxidant-stressed) cells. Intracellular replication of chromium-modified plasmids demonstrated increased mutagenicity of binary Cr(III)-DNA and ternary cysteine-Cr(III)-DNA adducts in cells with inactive NER. NER deficiency created by the loss of XPA in fibroblasts or by knockdown of this protein by stable expression of small interfering RNA in H460 cells increased apoptosis and clonogenic death by Cr(VI), providing genetic evidence for the role of monofunctional chromium-DNA adducts in the toxic effects of this metal. The rate of NER of chromium-DNA adducts under saturating conditions was calculated to be approximately 50,000 lesions/min/cell. Because chromium-DNA adducts cause only small changes in the DNA helix, rapid repair of these modifications in human cells indicates that the presence of major structural distortions in DNA is not required for the efficient detection of the damaged sites by NER proteins in vivo.

Differences in replication of a DNA template containing an ethyl phosphotriester by T4 DNA polymerase and Escherichia coli DNA polymerase I

A DNA template containing a single ethyl phosphotriester was replicated in vitro by the bacteriophage T4 DNA polymerase and by Escherichia coli DNA polymerase I (DNA pol I). Escherichia coli DNA pol I bypassed the lesion efficiently, but partial inhibition was observed for T4 DNA polymerase. The replication block produced by the ethyl phosphotriester was increased at low dNTP concentrations and for a mutant T4 DNA polymerase with an antimutator phenotype, increased proofreading activity, and reduced ability to bind DNA in the polymerase active center. These observations support a model in which an ethyl phosphotriester impedes primer elongation by T4 DNA polymerase by decreasing formation of the ternary DNA polymerase-DNA-dNTP complex. When primer elongation is not possible, proofreading becomes the favored reaction. Apparent futile cycles of nucleotide incorporation and proofreading, the idling reaction, were observed at the site of the lesion. The replication block was overcome by higher dNTP concentrations. Thus, ethyl phosphotriesters may be tolerated in vivo by the up-regulation of dNTP biosynthesis that occurs during the cellular checkpoint response to blocked DNA replication forks.

Hypersensitivity of DNA polymerase beta null mouse fibroblasts reflects accumulation of cytotoxic repair intermediates from site-specific alkyl DNA lesions

Monofunctional alkylating agents react with DNA by S(N)1 or S(N)2 mechanisms resulting in formation of a wide spectrum of cytotoxic base adducts. DNA polymerase beta (beta-pol) is required for efficient base excision repair of N-alkyl adducts, and we make use of the hypersensitivity of beta-pol null mouse fibroblasts to investigate such alkylating agents with a view towards understanding the DNA lesions responsible for the cellular phenotype. The inability of O(6)-benzylguanine to sensitize wild-type or beta-pol null cells to S(N)1-type methylating agents indicates that the observed hypersensitivity is not due to differential repair of cytotoxic O-alkyl adducts. Using a 3-methyladenine-specific agent and an inhibitor of such methylation, we find that inefficient repair of 3-methyladenine is not the reason for the hypersensitivity of beta-pol null cells to methylating agents, and further that 3-methyladenine is not the adduct primarily responsible for methyl methanesulfonate (MMS)- and methyl nitrosourea-induced cytotoxicity in wild-type cells. Relating the expected spectrum of DNA adducts and the relative sensitivity of cells to monofunctional alkylating agents, we propose that the hypersensitivity of beta-pol null cells reflects accumulation of cytotoxic repair intermediates, such as the 5'-deoxyribose phosphate group, following removal of 7-alkylguanine from DNA. In support of this conclusion, beta-pol null cells are also hypersensitive to the thymidine analog 5-hydroxymethyl-2'-deoxyuridine (hmdUrd). This agent is incorporated into cellular DNA and elicits cytotoxicity only when removed by glycosylase-initiated base excision repair. Consistent with the hypothesis that there is a common repair intermediate resulting in cytotoxicity following treatment with both types of agents, both MMS and hmdUrd-initiated cell death are preceded by a similar rapid concentration-dependent suppression of DNA synthesis and a later cell cycle arrest in G(0)/G(1) and G(2)M phases.

O6-Alkylguanine-DNA-alkyltransferase activity in peripheral leukocytes, smoking and risk of lung cancer

The level of activity of O6-alkylguanine-DNA-alkyltransferase (AGT), a DNA repair enzyme, in blood lymphocytes may be a marker of susceptibility to lung cancer. We measured the AGT activity level, expressed as pmoles of repaired bases/mg protein, in leukocytes of 153 lung cancer cases (of whom 80 were never smokers) and 106 controls (76 never smokers) enrolled in eight centres from seven countries. Subjects were interviewed with respect to active smoking and exposure to environmental tobacco smoke (ETS). Among never smokers, the odds ratios (ORs) of lung cancer were 1.3 (95% confidence interval 0.5-3.9), 1.5 (0.6-4.1) and 1.4 (0.5-3.8) in quartiles of decreasing AGT activity level, as compared to the upper quartile (P value of test for linear trend 0.6). Corresponding ORs among smokers were 3.4 (0.9-13), 2.0 (0.5-8.3) and 0.4 (0.1-1.6) (P value of test for linear trend 0.4). No interaction was suggested between AGT activity level and either cumulative smoking or exposure to ETS. Reduced AGT activity was not clearly associated with increased lung cancer risk in either smokers or non-smokers. However, the small size of our study argues for a prudent interpretation of our results.

Transcriptional responses to DNA damage

In Escherichia coli, DNA repair and protective responses are regulated at the transcriptional level. Regulatory mechanisms have evolved that allow cells to respond to DNA damage by mounting the appropriate responses. The regulatory proteins controlling these responses are activated when they recognize the presence of a specific DNA damaging agent, the production of specific DNA lesions, or the production of damage intermediates resulting from replication of lesions containing DNA. Transcription of the responses to DNA damage are induced when the activated regulatory proteins stimulate transcription of the genes they control by a variety of complex and unique molecular mechanisms.

Ada protein-RNA polymerase sigma subunit interaction and alpha subunit-promoter DNA interaction are necessary at different steps in transcription initiation at the Escherichia coli Ada and aidB promoters

The methylated form of the Ada protein (meAda) binds the ada and aidB promoters between 60 and 40 base pairs upstream from the transcription start and activates transcription of the Escherichia coli ada and aidB genes. This region is also a binding site for the alpha subunit of RNA polymerase and resembles the rrnB P1 UP element in A/T content and location relative to the core promoter. In this report, we show that deletion of the C-terminal domain of the alpha subunit severely decreases meAda-independent binding of RNA polymerase to ada and aidB, affecting transcription initiation at these promoters. We provide evidence that meAda activates transcription by direct interaction with the C-terminal domain of RNA polymerase sigma70 subunit (amino acids 574-613). Several negatively charged residues in the sigma70 C-terminal domain are important for transcription activation by meAda; in particular, a glutamic acid to valine substitution at position 575 has a dramatic effect on meAda-dependent transcription. Based on these observations, we propose that the role of the alpha subunit at ada and aidB is to allow initial binding of RNA polymerase to the promoters. However, transcription initiation is dependent on meAda-sigma70 interaction.

The potential role of glycine-160 of human O6-alkylguanine-DNA alkyltransferase in reaction with O6-benzylguanine as determined by site-directed mutagenesis and molecular modelling comparisons

O6-Alkylguanine DNA-alkyltransferase (ATase) repairs toxic, mutagenic and carcinogenic O6-alkylguanine (O6-alkG) lesions in DNA by a highly conserved reaction involving the stoichiometric transfer of the alkyl group to the active centre cysteine residue of the ATase protein. In the Escherichia coli Ada ATase, which is effectively refactory to inhibition by O6-benzylguanine (O6-BzG), the residue corresponding to glycine-160 (G160) for the mammalian proteins of this class is replaced by a tryptophan (W). Therefore, to investigate the potential role of the G160 of the human ATase (hAT) protein in determining sensitivity to O6-BzG, site-directed mutagenesis was used to produce a mutant protein (hATG160W) substituted at position 160 with a W residue. The hATG160W mutant was found to be stably expressed and was 3- and 5-fold more sensitive than hAT to inactivation by O6-BzG, in the absence and presence of additional calf-thymus DNA respectively. A similar, DNA dependent increased sensitivity of the hATG160W mutant relative to wild-type was also found for O6-methylguanine mediated inactivation. The potential role of the W160 residue in stabilising the binding of the O6-alkG to the protein is discussed in terms of a homology model of the structure of hAT. The region occupied by G/W-160 forms the site of a putative hinge that could be important in the conformational change that is likely to occur on DNA binding. Three sequence motifs have been identified in this region which may influence O6-BzG access to the active site; YSGG or YSGGG in mammals (YAGG in E. coli Ogt, YAGS in Dat from Bacillus subtilis), YRWG in E. coli Ada and Salmonella typhimurium (but YKWS in Saccharomyces cerevisiae) or YRGGF in AdaB from B. Subtilis. Finally,conformational and stereoelectronic analysis of the putative transition states for the alkyl transfer from a series of inactivators of hAT, including O6-BzG was undertaken to rationalise the unexpected weak inhibition shown by the alpha-pi-unsaturated electrophiles.

The RNA polymerase alpha subunit carboxyl-terminal domain is required for both basal and activated transcription from the alkA promoter

Expression of the Escherichia coli adaptive response genes (ada, aidB, and alkA) is regulated by the transcriptional activator, Ada. However, the interactions of RNA polymerase and Ada with these promoters differ. In this report we characterize the interactions of Ada, methylated Ada (meAda), and RNA polymerase at the alkA promoter and contrast these interactions with those characterized previously for the ada and aidB promoters. At the alkA promoter, we do not detect the RNA polymerase alpha subunit-mediated binary complex detected at the ada and aidB promoters. In the presence of either of these two activators, RNA polymerase protects the alkA core promoter, including the elements at -35 and -10, and is more efficient in transcription initiation in vitro. RNA polymerase holoenzyme containing the alpha subunit mutation R265A is severely impaired in Ada-independent basal alkA transcription, shows no activation by Ada or meAda, and fails to bind the alkA promoter in vitro. Binding of the purified wild type alpha subunit to alkA was not detected, but a complex of promoter DNA, Ada or meAda, and alpha was observed in gel shift assays. These observations suggest that both forms of Ada protein activate alkA transcription by enhancing RNA polymerase holoenzyme and alpha subunit binding.

Methyl Transfer to Mercury Thiolates: Effects of Coordination Number and Ligand Dissociation

The complexes [(CH(3))(4)N](2)[Hg(SC(6)H(5))(4)] and [(C(4)H(9))(4)N][Hg(SC(6)H(5))(3)] demethylate (CH(3)O)(3)PO as revealed by (1)H, (31)P{(1)H}, and (199)Hg{(1)H} NMR spectroscopy in DMSO-d(6) solution. The products of the [(CH(3))(4)N](2)[Hg(SC(6)H(5))(4)] reaction are CH(3)SC(6)H(5), (CH(3)O)(2)PO(2)(-), and [Hg(SC(6)H(5))(3)](-), whereas [Hg(SC(6)H(5))(3)](-) demethylates (CH(3)O)(3)PO to yield CH(3)SC(6)H(5) and {Hg(SC(6)H(5))(2)[(CH(3)O)(2)PO(2)]}(-). Kinetic and solution studies of [(CH(3))(4)N](2)[Hg(SC(6)H(5))(4)] reveal a rapid equilibrium between bound and free thiolate. The dissociated thiolate is the nucleophile active toward (CH(3)O)(3)PO. These results imply that the metal center of the inactive mercury derivative of the Escherichia coli Ada DNA alkylation repair protein may comprise a three-coordinate [Hg(S-cysteine)(3)](-) moiety and an unbound, protonated cysteine (HS-Cys69).

Alkyl Transfer to Metal Thiolates: Kinetics, Active Species Identification, and Relevance to the DNA Methyl Phosphotriester Repair Center of Escherichia coli Ada

The Ada protein of Escherichia coli employs a [Zn(S-cys)(4)](2)(-) site to repair deoxyribonucleic acid alkyl phosphotriester lesions. The alkyl group is transferred to a cysteine thiolate in a stoichiometric reaction. We describe a functional model for this chemistry in which a thiolate of [(CH(3))(4)N](2)[Zn(SC(6)H(5))(4)] accepts a methyl group from (CH(3)O)(3)PO. The thiolate salt (CH(3))(4)N(SC(6)H(5)) is also active in methyl transfer, but the thiol C(6)H(5)SH fails to react. Conductivity measurements and kinetic studies demonstrate that [(CH(3))(4)N](2)[Zn(SC(6)H(5))(4)] forms ion pairs in dimethyl sulfoxide (DMSO) solution (K(IP) = 13 +/- 4 M(-)(1)) which exhibit diminished reactivity. The reaction of [Zn(SC(6)H(5))(4)](2)(-) with (CH(3)O)(3)PO is first order with respect to each reagent. A second-order rate constant for this reaction, k(Zn), was determined to be (1.6 +/- 0.3) x 10(-)(2) M(-)(1) s(-)(1). From kinetic data and equilibria studies, all reactivity of [(CH(3))(4)N](2)[Zn(SC(6)H(5))(4)] toward (CH(3)O)(3)PO could be attributed to dissociated thiolate. Metal complexes representing alternative protein sites were prepared and displayed the following kinetic trend of methyl transfer ability: [(CH(3))(4)N](2)[Zn(SC(6)H(5))(4)] > [(CH(3))(4)N](2)[Co(SC(6)H(5))(4)] approximately [(CH(3))(4)N](2)[Cd(SC(6)H(5))(4)] > [(CH(3))(4)N][Zn(SC(6)H(5))(3)(MeIm)] > [Zn(SC(6)H(5))(2)(MeIm)(2)], where MeIm = 1-methylimidazole. These results are consistent with a dissociated thiolate being the active species and suggest that a similar mechanism might apply to alkyl phosphotriester repair by Ada.

Requirement for two conserved cysteine residues in the Ada protein of Escherichia coli for transactivation of the ada promoter

Cysteine residue 69 of the Escherichia coli Ada transcription factor, which accepts a methyl group from methylphosphotriester in methylated DNA, was substituted by each of 19 other amino acids. Only the mutant Ada (C69H), carrying a histidine substitution of Cys69, exhibited a limited degree of transactivating potential for the ada promoter in E. coli cells although the mutant protein was completely devoid of methylphosphotriester-DNA methyltransferase activity. Using a multicopy plasmid system for the expression of Ada protein, we have shown that Ada C69H has a transactivating capacity equivalent to that of wild-type Ada protein in the absence of an alkylating agent. This indicates that the zinc-binding capacity of histidine at residue 69 is likely to be sufficient for Ada to recognize and bind to the ada promoter. Furthermore, transactivation of the ada promoter by Ada C69H was enhanced up to 6-fold by treatment with methylating agents. An additional substitution was made with alanine in Ada C69H, replacing Cys321, the site for acceptance of a methyl group from O6-methylguanine and O4-methylthymine residues in DNA, with alanine. This renders the protein completely inactive as a methyltransferase but this derivative is constitutively active as a transactivator for the ada promoter. Therefore, acquisition of a methyl group at Cys321 apparently enhances the transactivating capacity of Ada protein on the ada promoter. We propose that the transcription-regulating function of Ada protein is under dual control by methylation of cysteine residues at positions 69 and 321; the former enhances DNA binding, while the latter enhances the transactivating capacity of the protein.

Metal dependence of transcriptional switching in Escherichia coli Ada

The Escherichia coli Ada protein repairs methylphosphotriesters in DNA by direct, irreversible methyl transfer to one of its own cysteine residues. The methyl transfer process is autocatalyzed by coordination of the acceptor residue, Cys69, to a tightly bound zinc ion. Kinetic data reveal a 4-fold reduction in the methylphosphotriester repair activity for the Cd(II) form of Ada versus the native Zn(II)-bound form, thus confirming a direct role for the metal in autocatalysis. Quantitative electrophoretic mobility shift assays reveal that the specific DNA affinity of the protein is increased 10(3)-fold by transfer of a methyl group to Cys69; the Cd(II) and the Zn(II) forms of the protein behave similarly in this respect. This methylation-sensitive stimulation of binding underlies the ability of Ada to activate inducibly the transcription of a methylation-dependent regulon. We conclude that the chemical properties of the bound metal influence the transition state for autocatalytic methyl transfer, but not the structure that ultimately results from this process.

Alteration of lysine 178 in the hinge region of the Escherichia coli ada protein interferes with activation of ada, but not alkA, transcription

The ada gene of Escherichia coli K-12 encodes the 39-kDa Ada protein, which consists of two domains joined by a hinge region that is sensitive to proteolytic cleavage in vitro. The amino-terminal domain has a DNA methyltransferase activity that repairs the S-diastereoisomer of methylphosphotriesters while the carboxyl-terminal domain has a DNA methyltransferase activity that repairs O6-methylguanine and O4-methylthymine lesions. Transfer of a methyl group to Cys-69 by repair of a methylphosphotriester lesion converts Ada into a transcriptional activator of the ada and alkA genes. Activation of ada, but not alkA, requires elements contained within the carboxyl-terminal domain of Ada. In addition, physiologically relevant concentrations of the unmethylated form of Ada specifically inhibit methylated Ada-promoted ada transcription both in vitro and in vivo and it has been suggested that this phenomenon plays a pivotal role in the down-regulation of the adaptive response. A set of site-directed mutations were generated within the hinge region, changing the lysine residue at position 178 to leucine, valine, glycine, tyrosine, arginine, cysteine, proline, and serine. All eight mutant proteins have deficiencies in their ability to activate ada transcription in the presence or absence of a methylating agent but are proficient in alkA activation. AdaK178P (lysine 178 changed to proline) is completely defective for the transcriptional activation function of ada while it is completely proficient for transcriptional activation of alkA. In addition, AdaK178P possesses both classes of DNA repair activities both in vitro and in vivo. Transcriptional activation of ada does not occur if both the amino- and carboxyl-terminal domains are produced separately within the same cell. The mutation at position 178 might interfere with activation of ada transcription by changing a critical contact with RNA polymerase, by causing a conformational change of Ada, or by interfering with the communication of conformational information between the amino- and the carboxyl-terminal domains. These results indicate that the hinge region of Ada is important for ada but not alkA transcription and further support the notion that the mechanism(s) by which Ada activates ada transcription differs from that by which it activates transcription at alkA.

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.

Low pH adaptation and the acid tolerance response of Salmonella typhimurium

Salmonella typhimurium periodically confronts acid environments during its life. These situations arise in chemically compromised ponds, soil, degradative cellular organelles, host digestive systems, and may even result from byproducts of their own metabolism. The levels of acid that are encountered range from mild to extreme. As a neutralophile, S. typhimurium prefers to grown in pH environments above pH 5.5. They can survive down to pH 4 for extended periods of time. However, the limits of endurance can be stretched if the organisms are first adapted to a moderate acid pH before exposing them to acidity below pH 4.0. This adaptation, called the acid-tolerance response (ATR), includes several log phase and stationary phase systems. Some of these systems are dependent on an alternate sigma factor for RNA polymerase called sigma s, whereas other systems are sigma s-independent. A key to the ATR is the synthesis of a series of acid shock inducible proteins (ASPs), 51 for log phase ATR and 15 for stationary phase ATR. Some of these ASPs require sigma s for their synthesis; others require the participation of the ferric uptake regulator protein Fur. Effective acid tolerance involves RecA-independent DNA repair systems, iron, and facets of fatty acid metabolism. Aspects of medium composition and carbon metabolism are also known to influence the nature of acid tolerance in this organism. In addition to aiding survival in the natural non-host environment, aspects of acid tolerance are also tied to virulence, as evidenced by the involvement of the mouse virulence locus mviA and the fact that acid-sensitive strains of S. typhimurium exhibit reduced virulence. This review summarizes these aspects of acid adaptation and includes a discussion of acid-regulated gene expression.

Effects of DNA repair deficiency on the mutational specificity in the lacZ gene of Escherichia coli

The mutational specificities of various chemical mutagens were compared in isogenic E. coli strains with different DNA repair capabilities (wild-type, uvrA, umuC, and uvrA umuC) in a reversion assay employing a set of mutant lacZ genes that can detect two types of transitions, four types of transversions, and five kinds of specific frameshift events. A uvrA derivative was more sensitive than the wild-type strain to 3-chloro-4-(dichloromethyl)-5-hydroxy-2(5H)-furanone for +1G, -1G, -2(C-G), +1A and -1A frameshifts, G.C-->A.T transitions, and G.C-->T.A transversions. In a uvrA background, G.C-->T.A transversions and +1G, +1A, and -1A frameshifts appeared to be umuC-dependent, while G.C-->A.T transitions were not. N-Ethyl-N'-nitro-N-nitrosoguanidine was more mutagenic in a uvrA background for five kinds of frameshifts and G.C-->A.T transitions, but not for G.C-->T.A, A.T-->C.G, and A.T-->G.C base substitutions. A.T-->C.G transversions were totally dependent on umuC gene function. For the investigation of mutational specificities induced by frameshift mutagens, an rfa mutation was additionally introduced. The rfa strain responded to 2-nitrofluorene, which induced primarily -2(C-G) frameshift mutations. In an rfa uvrA background, benzo[a]pyrene induced +1G, -1G, +1A, and -1A frameshifts. 2-Aminoanthracene induced +1G, -1G, and +1A, but not -1A, frameshifts, with -1G frameshifts predominating. Ethidium bromide induced only two types of frameshifts, -1G and +1A. Frameshifts induced by ICR-170 were independent of umuC gene function, while those by induced 1-nitropyrene were partly umuC-dependent.

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.

On the quantitative relationship between O6-methylguanine residues in genomic DNA and production of sister-chromatid exchanges, mutations and lethal events in a Mer- human tumor cell line

O6-Methylguanine (m6G) is an altered base produced in DNA by SN1 methylating agents such as N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). This lesion is repaired by the protein O6-methylguanine-DNA methyltransferase (MGMT) in normal human cell lines, but is not repaired in certain human tumor lines that are termed Mex- or Mer-. Compared with repair-proficient cell lines, such repair-deficient tumor lines are hypersensitive to the production by MNNG of sister-chromatid exchanges (SCE), mutations and lethality. We report here that MNNG treatment produces 1 SCE for every 42 +/- 10 m6G formed in the genome of Mer- tumor cells, 1 6TG-resistant mutant for every 8 (range of 5-14) m6G produced statistically in the coding region of the hypoxanthine phosphoribosyltransferase gene, and 1 lethal event per 6650 +/- 1200 m6G. In addition, in vitro base mismatch incision at m6G: BrU pairs was similar to that at m6G: T pairs, the lesions that likely initiate SCE production. We conclude that m6G residues in genomic DNA are very recombinogenic as well as highly mutagenic in Mer- human tumor cells. The results are interpreted in terms of the relationship between methylation-induced SCE and G: T mismatch recognition.

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.

New method for gene disruption in Salmonella typhimurium: construction and characterization of an ada-deletion derivative of Salmonella typhimurium TA1535

A new method for gene disruption in Salmonella typhimurium was developed. The key steps of this method are to produce restriction fragments with compatible ends, preligate to produce concatemers, and then transform by electrotransformation. We developed and used this method to construct a mutant of S. typhimurium TA1535 in which the resident ada-like (adaST) gene was replaced with a kanamycin resistance gene to produce an adaST-deletion mutant derivative. The S. typhimurium adaST-deletion strain did not exhibit a higher level of mutability upon treatment with N-methyl-N'-nitro-N-nitrosoguanidine than did its wild-type parent strain. However, it did exhibit a higher sensitivity with respect to killing by N-methyl-N'-nitro-N-nitrosoguanidine. The ability of AdaST to function as a transcriptional activator is discussed.

Alkylation and oxidative-DNA damage repair activity in blood leukocytes of smokers and non-smokers

The levels of 3 DNA repair enzymes involved in alkylation and oxidative DNA damage repair in human peripheral blood leukocytes were measured in 20 smokers and 17 non-smokers. No differences in O6-alkylguanine-DNA-alkyltransferase (AGT) activity were found between the 2 groups and the AGT distribution within the population appeared to be unimodal. In contrast, the mean activities of both the methylpurine (MeP)- and the 2-6-diamino-4-hydroxy-5N formamidopyrimidine (FaPy)-DNA glycosylases were higher in the smokers, although only the difference between the MeP-DNA glycosylase means was statistically significant. The standard deviations of these 2 enzymes were also higher in the smokers. The MeP-DNA glycosylase activity showed a bimodal distribution when all subjects were considered. This may in part be due to the smoking habit; 83% of the subjects with enzyme activities higher than 500 fmoles/mg protein were current smokers, whilst 85% of the non-smokers had lower enzyme activities. However, if the smokers were considered separately, a bimodal distribution of this enzyme activity could still be observed. No strong correlation was observed between enzyme activity and age, although the slopes of the regression lines of enzyme activity on age were all negative. The relationship between enzyme activities was studied by bivariate distribution and a strong correlation was only found between the MeP-DNA glycosylase and the FaPy-glycosylase, with the highest values of both enzyme activities being observed in the smokers and the lowest in the non-smokers. Our results suggest that the activity of certain DNA repair enzymes can be modulated by environmental exposure.

Large-scale mutational analysis of EMS-induced mutation in the lacI gene of Escherichia coli

Mutational spectra produced by mutagens in various repair backgrounds can provide important information about the roles of different repair systems in the mutagenic process. Until recently, such studies have been restricted to the characterisation of comparatively small numbers of mutants or reversion analysis at relatively few sites. The colony hybridisation method used in this study in conjunction with DNA sequencing allows the characterisation of large numbers of mutants and therefore allows analysis of resultant mutational distributions to be made with confidence. We have determined the DNA alterations recovered after treatment with EMS in the N-terminal region of the lacI gene of E. coli. A total of 1138 and 1102 independent lacI-d mutants were characterised in Uvr+ and UvrB-, respectively. Consistent with the known ethylating ability of this compound, the predominant mutation was G:C-->A:T transitions, which accounted for 97% and 93% in Uvr+ and UvrB- strains, respectively. An analysis of the DNA context of mutation induction indicates differential reparability by the Uvr repair pathway. Excision repair appears to more efficiently counter EMS-induced G:C-->A:T transitions at sites flanked by A:T base pairs. However, the influence of excision repair on the ultimate distribution of mutation can not be easily defined with respect to neighbouring sequence.

Mutation enhancing effect of o-vanillin in the lacZ gene of Escherichia coli: characterization of mutational spectrum

The enhancing effect of o-vanillin (2-hydroxy-3-methoxybenz-aldehyde) on mutations induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) was characterized with mutational specificity. The mutational spectrum of MNNG-induced mutations in the presence of o-vanillin was compared with that in the absence of o-vanillin by means of a series of mutant lacZ genes in E. coli that can detect each of the six types of base substitutions and five kinds of frameshift events. In the absence of o-vanillin, the mutational spectrum induced by MNNG consisted mainly of G.C-->A.T transitions and, to a lesser extent, -1(G.C) frameshift mutations. By adding o-vanillin at 75 micrograms/plate, a marked enhancement was observed in two transitions, G.C-->A.T and A.T-->G.C, and in two frameshift mutations, +1(G.C) and -1(G.C). Only a small change was observed in the -2(C.G-G.C) fraction. Regarding the MNNG-induced frameshifts at the A.T base pair, the +1(A.T) frameshift was much more enhanced by o-vanillin than the -1(A.T) frameshift.

Induction of the adaptive response of Escherichia coli to alkylation damage by the environmental mutagen, methyl chloride

Methyl chloride (MeCl) is an abundant environmental mutagen and carcinogen and may be one of several environmental alkylating agents against which the protection of an adaptive response is required in microorganisms. Both MeCl and methyl iodide (MeI), at micromolar concentrations, induced the adaptive response to alkylation damage in Escherichia coli. This response is regulated by the Ada protein which is converted into a transcriptional activator by self-methylation on repair of methylphosphotriesters in methylated DNA. However, using high amounts of Ada protein, activation of Ada occurred in vitro following direct protein methylation by both MeI (in agreement with previously published data) and MeCl. Activation was enhanced when methyl halide treatments were performed in the presence of DNA. An unadapted E. coli cell contains only 2 to 4 molecules of Ada protein, and presents an extremely small target of 2 to 4 specific cysteine residues per cell for activation of Ada by direct protein methylation in vivo. Thus, it is proposed that induction of the adaptive response in vivo initially occurs via efficient repair by the Ada protein of a low number of methylphosphotriesters in DNA. When the cellular Ada protein level has substantially increased, a greater probability of direct methylation and activation of Ada at cysteine-69 by MeCl may sustain and further increase induction of the adaptive response.

Regulatory elements for expression of the alkA gene in response to alkylating agents

Expression of the alkA gene in Escherichia coli is controlled by Ada protein, which binds to a specific region of the alkA promoter and enhances further binding of RNA polymerase holoenzyme to the complex. To determine the sequence recognized by the Ada protein, we introduced various base substitutions into the promoter region of alkA and examined their effects on expression of the gene, both in vivo and in vitro. Base changes within the sequence AAAGCAAA, located between positions -41 and -34 from the transcription initiation site, greatly decreased the frequencies of initiation of transcription. In footprinting experiments, the region containing this sequence was protected by the Ada protein and base changes within this sequence led to failure of binding of Ada protein to the promoter. It is likely that the Ada protein recognizes the AAAGCAAA sequence in the alkA promoter and binds to the region containing the sequence, thereby allowing ready access of RNA polymerase to the promoter. There are considerable differences between the mechanisms of action of Ada protein on the promoters of alkA and ada, even though the expression of both genes is positively regulated by Ada protein.

Inducible alkyltransferase DNA repair proteins in the filamentous fungus Aspergillus nidulans

We have investigated the response of the filamentous fungus Aspergillus nidulans to low, non-killing, doses of the alkylating agent MNNG (N-methyl-N'-nitro-N-nitrosoguanidine). Such treatment causes a substantial induction of DNA alkyltransferase activity, with the specific activity in treated cells increasing up to one hundred-fold. Fluorography reveals the two main inducible species as proteins of 18.5 kDa and 21 kDa, both of which have activity primarily against O6-methylguanine (O6-MeG) lesions. In addition, two other alkyltransferase proteins can also be detected. One, of MW 16 kDa, is expressed in non-treated cells, but is not induced to the same extent as the 18.5 and 21 kDa proteins. The other, a protein of 19.5 kDa, is highly inducible and can only be detected in treated cells. Unlike the other three proteins, it acts primarily against methyl-phosphotriester (Me-PT) lesions. This is the first instance in which an MePT alkyltransferase has been detected in a eukaryotic organism and, coupled with the high level of induction of the O6-MeG alkyltransferase enzymes, this indicates that a control system similar to the bacterial adaptive response may be present in filamentous fungi.

Isolation and partial characterization of murine O6-alkylguanine-DNA-alkyltransferase: comparative sequence and structural properties

A cDNA encoding murine O6-alkylguanine-DNA-alkyltransferase (ATase) has been sequenced after isolation from total liver RNA by the polymerase chain reaction using oligonucleotide primers derived from the rat ATase cDNA sequence. Functionally active murine ATase protein has been expressed in Escherichia coli at high levels (about 2% of total protein) and purified to apparent homogeneity (molecular mass 26 kDa). In liquid hybridization experiments, anti-human ATase polyclonal antibodies inhibited human but not rat or mouse ATase, whereas anti-rat polyclonal antibodies inhibited rat and mouse but not human ATase. Both antibodies detected all mammalian ATases tested by western analysis so far. These results indicate some common epitopes and at least one unique human epitope. We compared the amino-acid sequence of the murine ATase with those of other mammalian and bacterial ATases. The proteins of this family all have a large domain (approximately 70 amino acids) of highly conserved residues flanking the sequence PCHRV, which contains the alkyl-accepting cysteine residue of the active site. No evidence was found in the sequences for helix-turn-helix, leucine-zipper, or zinc-finger motifs for DNA recognition and binding. Nuclear localization signals (basic-residue-rich regions) could not be uniquely identified in the mammalian members of the family. Outside of the conserved PCHRV region, there were major differences between prokaryotic and eukaryotic proteins at the primary structure level: there was a series of proline-rich motifs, but these also varied between sequences.

Lack of effects of selenium on N-nitrosomethylbenzylamine-induced tumorigenesis, DNA methylation, and oncogene expression in rats and mice

The effects of dietary selenium deficiency and excess on N-nitrosomethylbenzylamine-(NMBA) induced esophageal neoplasia in rats and forestomach tumors in mice and the effects of dietary selenium on DNA adduct formation and on the activities of DNA adduct-repairing enzyme and oncogene expression in rat esophagus were investigated. The esophageal and forestomach tumors were induced by administration of NMBA by gavage with a total dose of 39 mg/kg body wt in rats and 12 mg/kg body wt in mice. Neither selenium dietary deficiency (Se < 0.02 ppm) nor selenium excess (2.0 ppm) showed any significant effect on the incidence of tumors or number of tumors per tumor-bearing animal. For the DNA adduct formation studies, rats were given a dose of NMBA intraperitoneally after six weeks on the different selenium-containing diets. No significant difference in the amount of the DNA adduct O6-methyldeoxyguanosine was found among the different selenium-treated groups. In a parallel group of rats that did not receive NMBA, the levels of esophageal O6-methyldeoxyguanosine DNA methyltransferase were not significantly altered by dietary selenium levels. The c-myc oncogene expression in rat esophagus was induced by the administration of NMBA (3 mg/kg body wt) by gavage once a week for eight weeks. Dietary selenium did not show any effects on its expression. On the basis of the results of these studies, dietary selenium has no effects in the NMBA-induced tumor model.

Induction of the alkA gene of Escherichia coli in gram-negative bacteria

A broad-host-range plasmid containing a fusion of the alkA and lacZ genes of Escherichia coli was introduced into various aerobic and facultative gram-negative bacteria--33 species belonging to 19 genera--to study the induction of expression of the alkA gene by alkylating agents. The bacteria included species of the families Enterobacteriaceae, Pseudomonadaceae, Rhizobiaceae, Vibrionaceae, Neisseriaceae, Rhodospirillaceae, and Azotobacteraceae. Results obtained show that all bacteria tested, except Aeromonas hydrophila, Agrobacterium tumefaciens, Hafnia alvei, Rhizobium meliloti, Salmonella enteritidis, Xanthomonas campestris, and those of the genus Rhodobacter, are able to induce the alkA gene of E. coli in the presence of N-methyl-N'-nitro-N-nitrosoguanidine. All these data indicate that the adaptive response to alkylating agents is present in bacterial species of several families and that the Ada box sequence must be widely conserved.

A region of the Ada DNA-repair protein required for the activation of ada transcription is not necessary for activation of alkA

The adaptive response of Escherichia coli protects cells against the mutagenic and toxic effects of alkylating agents. This response is controlled by the Ada protein, which not only functions as the transcriptional activator of the ada and alkA genes but also possesses two DNA methyltransferae activities. Ada is converted into an efficient transcriptional activator by transferring a methyl group from a DNA methylphosphotriester to its own Cys-69 residue and then binds to a DNA sequence (the Ada box) present in both the ada and alkA promoters. Although the Ada protein initially appeared to regulate the ada and alkA genes in a similar fashion, our studies show that the wild-type Ada protein and its truncated derivatives can differentially regulate ada and alkA transcription. In vivo, lower levels of wild-type methylated Ada are needed to activate ada transcription than alkA transcription. In cells exposed to alkylating agents, the N-terminal half of Ada, which contains the DNA-binding domain, is sufficient for efficient activation of alkA, but not ada, transcription. Moreover, truncated derivatives containing 80-90% of Ada are extremely strong constitutive activators of ada but are only inducible activators of alkA transcription. These results suggest that the mechanism by which Ada activates ada transcription differs from that by which it activates alkA transcription.

Molecular analysis of the aidD6::Mu d1 (bla lac) fusion mutation of Escherichia coli K12

In this report we present genetic and biochemical evidence indicating that the aidD6::Mu d1 (bla lac) fusion is an insertion of Mu d1 (bla lac) into the alkB coding sequence. We describe the phenotypic effects resulting from this mutation and compare them with the effects of alkB22, alkA and ada mutations. We also constructed an alkA alkB double mutant and compared its phenotype with that of the single mutant strains. The observation that the methyl methanesulfonate (MMS) and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) resistance of the double mutant is approximately at the level predicted from the additive sensitivity of each of the single mutants suggests that these two gene products act in different pathways of DNA repair.