Characterisation and nucleotide sequence of ogt, the O6-alkylguanine-DNA-alkyltransferase gene of E. coli

The Versatile Attributes of MGMT: Its Repair Mechanism, Crosstalk with Other DNA Repair Pathways, and Its Role in Cancer

O6-methylguanine-DNA methyltransferase (MGMT or AGT) is a DNA repair protein with the capability to remove alkyl groups from O6-AlkylG adducts. Moreover, MGMT plays a crucial role in repairing DNA damage induced by methylating agents like temozolomide and chloroethylating agents such as carmustine, and thereby contributes to chemotherapeutic resistance when these agents are used. This review delves into the structural roles and repair mechanisms of MGMT, with emphasis on the potential structural and functional roles of the N-terminal domain of MGMT. It also explores the development of cancer therapeutic strategies that target MGMT. Finally, it discusses the intriguing crosstalk between MGMT and other DNA repair pathways.

The DNA Alkyltransferase Family of DNA Repair Proteins: Common Mechanisms, Diverse Functions

DNA alkyltransferase and alkyltransferase-like family proteins are responsible for the repair of highly mutagenic and cytotoxic O6-alkylguanine and O4-alkylthymine bases in DNA. Their mechanism involves binding to the damaged DNA and flipping the base out of the DNA helix into the active site pocket in the protein. Alkyltransferases then directly and irreversibly transfer the alkyl group from the base to the active site cysteine residue. In contrast, alkyltransferase-like proteins recruit nucleotide excision repair components for O6-alkylguanine elimination. One or more of these proteins are found in all kingdoms of life, and where this has been determined, their overall DNA repair mechanism is strictly conserved between organisms. Nevertheless, between species, subtle as well as more extensive differences that affect target lesion preferences and/or introduce additional protein functions have evolved. Examining these differences and their functional consequences is intricately entwined with understanding the details of their DNA repair mechanism(s) and their biological roles. In this review, we will present and discuss various aspects of the current status of knowledge on this intriguing protein family.

Archaeal DNA alkylation repair conducted by DNA glycosylase and methyltransferase

Alkylated bases in DNA created in the presence of endogenous and exogenous alkylating agents are either cytotoxic or mutagenic, or both to a cell. Currently, cells have evolved several strategies for repairing alkylated base. One strategy is a base excision repair process triggered by a specific DNA glycosylase that is used for the repair of the cytotoxic 3-methyladenine. Additionally, the cytotoxic and mutagenic O⁶-methylguanine (O⁶-meG) is corrected by O⁶-methylguanine methyltransferase (MGMT) via directly transferring the methyl group in the lesion to a specific cysteine in this protein. Furthermore, oxidative DNA demethylation catalyzed by DNA dioxygenase is utilized for repairing the cytotoxic 3-methylcytosine (3-meC) and 1-methyladenine (1-meA) in a direct reversal manner. As the third domain of life, Archaea possess 3-methyladenine DNA glycosylase II (AlkA) and MGMT, but no DNA dioxygenase homologue responsible for oxidative demethylation. Herein, we summarize recent progress in structural and biochemical properties of archaeal AlkA and MGMT to gain a better understanding of archaeal DNA alkylation repair, focusing on similarities and differences between the proteins from different archaeal species and between these archaeal proteins and their bacterial and eukaryotic relatives. To our knowledge, it is the first review on archaeal DNA alkylation repair conducted by DNA glycosylase and methyltransferase. KEY POINTS: • Archaeal MGMT plays an essential role in the repair of O ⁶ -meG • Archaeal AlkA can repair 3-meC and 1-meA.

Knockout of SlALKBH2 weakens the DNA damage repair ability of tomato

During the growth and evolution of plants, genomic DNA is subject to constant assault from endogenous and environmental DNA damage compounds, which will result in mutagenic or genotoxic covalent adducts. Whether for prokaryotes, eukaryotes or even viruses, maintaining genome integrity is critical for the continuation of life. Escherichia coli and mammals have evolved the AlkB family of Fe(II)/alpha-ketoglutarate-dependent dioxygenases that repair DNA alkylation damage. We identified a functional homologue with EsAlkB and HsALKBH2 in tomatoes, and named it SlALKBH2. In our study, the SlALKBH2 knockout mutant showed hypersensitivity to the DNA mutagen MMS and displayed more severe growth abnormalities than wild-type plants under mutagen treatment, such as slow growth, leaf deformation and early senescence. Additionally, genes with high transcriptional activity, such as rDNA, have increased methylation under MMS treatment. In conclusion, this study shows that the tomato SlALKBH2 gene may play an important role in ensuring the integrity of the genome.

Activation by NarL at the Escherichia coli ogt promoter

The Escherichia coli NarX/NarL two-component response-regulator system regulates gene expression in response to nitrate ions and the NarL protein is a global transcription factor, which activates transcript initiation at many target promoters. One such target, the E. coli ogt promoter, which controls the expression of an O6-alkylguanine-DNA-alkyltransferase, is dependent on NarL binding to two DNA targets centred at positions -44.5 and -77.5 upstream from the transcript start. Here, we describe ogt promoter derivatives that can be activated solely by NarL binding either at position -44.5 or position -77.5. We show that NarL can also activate the ogt promoter when located at position -67.5. We present data to argue that NarL-dependent activation of transcript initiation at the ogt promoter results from a direct interaction between NarL and a determinant in the C-terminal domain of the RNA polymerase α subunit. Footprinting experiments show that, at the -44.5 promoter, NarL and the C-terminal domain of the RNA polymerase α subunit bind to opposite faces of promoter DNA, suggesting an unusual mechanism of transcription activation. Our work suggests new organisations for activator-dependent transcription at promoters and future applications for biotechnology.

Direct DNA Lesion Reversal and Excision Repair in Escherichia coli

Cellular DNA is constantly challenged by various endogenous and exogenous genotoxic factors that inevitably lead to DNA damage: structural and chemical modifications of primary DNA sequence. These DNA lesions are either cytotoxic, because they block DNA replication and transcription, or mutagenic due to the miscoding nature of the DNA modifications, or both, and are believed to contribute to cell lethality and mutagenesis. Studies on DNA repair in Escherichia coli spearheaded formulation of principal strategies to counteract DNA damage and mutagenesis, such as: direct lesion reversal, DNA excision repair, mismatch and recombinational repair and genotoxic stress signalling pathways. These DNA repair pathways are universal among cellular organisms. Mechanistic principles used for each repair strategies are fundamentally different. Direct lesion reversal removes DNA damage without need for excision and de novo DNA synthesis, whereas DNA excision repair that includes pathways such as base excision, nucleotide excision, alternative excision and mismatch repair, proceeds through phosphodiester bond breakage, de novo DNA synthesis and ligation. Cell signalling systems, such as adaptive and oxidative stress responses, although not DNA repair pathways per se, are nevertheless essential to counteract DNA damage and mutagenesis. The present review focuses on the nature of DNA damage, direct lesion reversal, DNA excision repair pathways and adaptive and oxidative stress responses in E. coli.

Molecular characterization of an adaptive response to alkylating agents in the opportunistic pathogen Aspergillus fumigatus

An adaptive response to alkylating agents based upon the conformational change of a methylphosphotriester (MPT) DNA repair protein to a transcriptional activator has been demonstrated in a number of bacterial species, but this mechanism appears largely absent from eukaryotes. Here, we demonstrate that the human pathogen Aspergillus fumigatus elicits an adaptive response to sub-lethal doses of the mono-functional alkylating agent N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). We have identified genes that encode MPT and O(6)-alkylguanine DNA alkyltransferase (AGT) DNA repair proteins; deletions of either of these genes abolish the adaptive response and sensitize the organism to MNNG. In vitro DNA repair assays confirm the ability of MPT and AGT to repair methylphosphotriester and O(6)-methylguanine lesions respectively. In eukaryotes, the MPT protein is confined to a select group of fungal species, some of which are major mammalian and plant pathogens. The evolutionary origin of the adaptive response is bacterial and rooted within the Firmicutes phylum. Inter-kingdom horizontal gene transfer between Firmicutes and Ascomycete ancestors introduced the adaptive response into the Fungal kingdom. Our data constitute the first detailed characterization of the molecular mechanism of the adaptive response in a lower eukaryote and has applications for development of novel fungal therapeutics targeting this DNA repair system.

Multifaceted roles of alkyltransferase and related proteins in DNA repair, DNA damage, resistance to chemotherapy, and research tools

O(6)-Alkylguanine-DNA alkyltransferase (AGT) is a widely distributed, unique DNA repair protein that acts as a single agent to directly remove alkyl groups located on the O(6)-position of guanine from DNA restoring the DNA in one step. The protein acts only once, and its alkylated form is degraded rapidly. It is a major factor in counteracting the mutagenic, carcinogenic, and cytotoxic effects of agents that form such adducts including N-nitroso-compounds and a number of cancer chemotherapeutics. This review describes the structure, function, and mechanism of action of AGTs and of a family of related alkyltransferase-like proteins, which do not act alone to repair O(6)-alkylguanines in DNA but link repair to other pathways. The paradoxical ability of AGTs to stimulate the DNA-damaging ability of dihaloalkanes and other bis-electrophiles via the formation of AGT-DNA cross-links is also described. Other important properties of AGTs include the ability to provide resistance to cancer therapeutic alkylating agents, and the availability of AGT inhibitors such as O(6)-benzylguanine that might overcome this resistance is discussed. Finally, the properties of fusion proteins in which AGT sequences are linked to other proteins are outlined. Such proteins occur naturally, and synthetic variants engineered to react specifically with derivatives of O(6)-benzylguanine are the basis of a valuable research technique for tagging proteins with specific reagents.

Chemical biology of mutagenesis and DNA repair: cellular responses to DNA alkylation

The reaction of DNA-damaging agents with the genome results in a plethora of lesions, commonly referred to as adducts. Adducts may cause DNA to mutate, they may represent the chemical precursors of lethal events and they can disrupt expression of genes. Determination of which adduct is responsible for each of these biological endpoints is difficult, but this task has been accomplished for some carcinogenic DNA-damaging agents. Here, we describe the respective contributions of specific DNA lesions to the biological effects of low molecular weight alkylating agents.

Competition between NarL-dependent activation and Fis-dependent repression controls expression from the Escherichia coli yeaR and ogt promoters

The Escherichia coli NarL protein is a global gene regulatory factor that activates transcription at many target promoters in response to nitrate and nitrite ions. Although most NarL-dependent promoters are also co-dependent on a second transcription factor, FNR protein, two targets, the yeaR and ogt promoters, are activated by NarL alone with no involvement of FNR. Biochemical and genetic studies presented here show that activation of the yeaR promoter is dependent on the binding of NarL to a single target centred at position −43.5, whereas activation at the ogt promoter requires NarL binding to tandem DNA targets centred at position −45.5 and −78.5. NarL-dependent activation at both the yeaR and ogt promoters is decreased in rich medium and this depends on Fis, a nucleoid-associated protein. DNase I footprinting studies identified Fis-binding sites that overlap the yeaR promoter NarL site at position −43.5, and the ogt promoter NarL site at position −78.5, and suggest that Fis represses both promoters by displacing NarL. The ogt gene encodes an O6-alkylguanine DNA alkyltransferase and, hence, this is the first report of expression of a DNA repair function being controlled by nitrate ions.

The alkyltransferase-like ybaZ gene product enhances nucleotide excision repair of O(6)-alkylguanine adducts in E. coli

O(6)-methylguanine adducts are potent pre-mutagenic lesions owing to their high capacity to direct mis-insertion of thymine when bypassed by replicative DNA polymerases. The strong mutagenic potential of these adducts is prevented by alkyltransferases such as Ada and Ogt in Escherichia coli that transfer the methyl group to one of their cysteine residues. Alkyl residues larger than methyl are generally weak substrates for reversion by alkyltransferases. In this paper we have investigated the genotoxic potential of the O(6)-alkylguanine adducts formed by ethylene and propylene oxide using single-adducted plasmid probes. Our work shows that the ybaZ gene product, a member of the alkyltransferase-like protein family, strongly enhances the repair by nucleotide excision repair of the larger O(6)-alkylguanine adducts that are otherwise poor substrates for alkyltransferases. The YbaZ protein is shown to interact with UvrA. This factor may thus enhance the efficiency of nucleotide excision repair in a way similar to the Transcription-Repair Coupling factor Mfd, by recruiting the UvrA(2).UvrB complex to the adduct site via its interaction with UvrA.

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.

Mismatch repair proteins collaborate with methyltransferases in the repair of O(6)-methylguanine

DNA repair is essential for combatting the adverse effects of damage to the genome. One example of base damage is O(6)-methylguanine (O(6)mG), which stably pairs with thymine during replication and thereby creates a promutagenic O(6)mG:T mismatch. This mismatch has also been linked with cellular toxicity. Therefore, in the absence of repair, O(6)mG:T mismatches can lead to cell death or result in G:C-->A:T transition mutations upon the next round of replication. Cysteine thiolate residues on the Ada and Ogt methyltransferase (MTase) proteins directly reverse the O(6)mG base damage to yield guanine. When a cytosine is opposite the lesion, MTase repair restores a normal G:C pairing. However, if replication past the lesion has produced an O(6)mG:T mismatch, MTase conversion to a G:T mispair must still undergo correction to avoid mutation. Two mismatch repair pathways in E. coli that convert G:T mispairs to native G:C pairings are methyl-directed mismatch repair (MMR) and very short patch repair (VSPR). This work examined the possible roles that proteins in these pathways play in coordination with the canonical MTase repair of O(6)mG:T mismatches. The possibility of this repair network was analyzed by probing the efficiency of MTase repair of a single O(6)mG residue in cells deficient in individual mismatch repair proteins (Dam, MutH, MutS, MutL, or Vsr). We found that MTase repair in cells deficient in Dam or MutH showed wild-type levels of MTase repair. In contrast, cells lacking any of the VSPR proteins MutS, MutL, or Vsr showed a decrease in repair of O(6)mG by the Ada and Ogt MTases. Evidence is presented that the VSPR pathway positively influences MTase repair of O(6)mG:T mismatches, and assists the efficiency of restoring these mismatches to native G:C base pairs.

MGMT: a personal perspective

This review describes the history of studies on alkylation damage of mammalian genomes and its carcinogenic consequences that led to the discovery of a unique DNA repair protein, named MGMT. MGMT repairs O(6)-alkylguanine, a critical mutagenic lesion induced by alkylating agents. The follow-up studies in mammalian cells following the discovery of the ubiquitous repair protein in E. coli are summarized.

A novel DNA damage recognition protein in Schizosaccharomyces pombe

Toxic and mutagenic O⁶-alkylguanine adducts in DNA are repaired by O⁶-alkylguanine-DNA alkyltransferases (MGMT) by transfer of the alkyl group to a cysteine residue in the active site. Comparisons in silico of prokaryotes and lower eukaryotes reveal the presence of a group of proteins [alkyltransferase-like (ATL) proteins] showing amino acid sequence similarity to MGMT, but where the cysteine at the putative active site is replaced by tryptophan. To examine whether ATL proteins play a role in the biological effects of alkylating agents, we inactivated the gene, referred to as atl1⁺, in Schizosaccharomyces pombe, an organism that does not possess a functional MGMT homologue. The mutants are substantially more susceptible to the toxic effects of the methylating agents, N-methyl-N-nitrosourea, N-methyl-N′nitro-N-nitrosoguanidine and methyl methanesulfonate and longer chain alkylating agents including N-ethyl-N-nitrosourea, ethyl methanesulfonate, N-propyl-N-nitrosourea and N-butyl-N-nitrosourea. Purified Atl1 protein does not transfer methyl groups from O⁶-methylguanine in [³H]-methylated DNA but reversibly inhibits methyl transfer by human MGMT. Atl1 binds to short single-stranded oligonucleotides containing O⁶-methyl, -benzyl, -4-bromothenyl or -hydroxyethyl-guanine but does not remove the alkyl group or base and does not cleave the oligonucleotide in the region of the lesion. This suggests that Atl1 acts by binding to O⁶-alkylguanine lesions and signalling them for processing by other DNA repair pathways. This is the first report describing an activity that protects S.pombe against the toxic effects of O⁶-alkylguanine adducts and the biological function of a family of proteins that is widely found in prokaryotes and lower eukaryotes.

A quest to understand molecular mechanisms for genetic stability

In the midst of the post-war turmoil in Japan, I fortunately followed a path to become a scientist. Sometime at an early stage of my career, I encountered the problem of the cellular response to DNA damage and had the chance to discover a DNA repair enzyme. This event greatly influenced the subsequent course of my research, and I extended my studies toward elucidating the molecular mechanisms of mutagenesis as well as of carcinogenesis. Through these studies I came to understand the importance of mechanisms for dealing with the actions of reactive oxygen species to the living systems. These recollections deal with these endeavors with emphasis on the early part of my scientific career.

Inhibition of O6-methylguanine-DNA methyltransferase by an alkyltransferase-like protein from Escherichia coli

The alkyltransferase-like (ATL) proteins contain primary sequence motifs resembling those found in DNA repair O⁶-alkylguanine-DNA alkyltransferase proteins. However, in the putative active site of ATL proteins, a tryptophan (W⁸³) residue replaces the cysteine at the known active site of alkyltransferases. The Escherichia coli atl gene was expressed as a fusion protein and purified. Neither ATL nor C⁸³ or A⁸³ mutants transferred [³H] from [³H]-methylated DNA to themselves, and the levels of O⁶-methyl guanine (O⁶-meG) in substrate DNA were not affected by ATL. However, ATL inhibited the transfer of methyl groups to human alkyltransferase (MGMT). Inhibition was reduced by prolonged incubation in the presence of MGMT, again suggesting that O⁶-meG in the substrate is not changed by ATL. Gel-shift assays show that ATL binds to short single- or double-stranded oligonucleotides containing O⁶-meG, but not to oligonucleotides containing 8-oxoguanine, ethenoadenine, 5-hydroxycytosine or O⁴-methylthymine. There was no evidence of demethylation of O⁶-meG or of glycosylase or endonuclease activity. Overexpression of ATL in E.coli increased, or did not affect, the toxicity of N-methyl-N′-nitro-N-nitrosoguanidine in an alklyltransferase-proficient and -deficient strain, respectively. These results suggest that ATL may act as a damage sensor that flags O⁶-meG and possibly other O⁶-alkylation lesions for processing by other repair pathways.

How heterologously expressed Escherichia coli genes contribute to understanding DNA repair processes in Saccharomyces cerevisiae

DNA-damaging agents constantly challenge cellular DNA; and efficient DNA repair is therefore essential to maintain genome stability and cell viability. Several DNA repair mechanisms have evolved and these have been shown to be highly conserved from bacteria to man. DNA repair studies were originally initiated in very simple organisms such as Escherichia coli and Saccharomyces cerevisiae, bacteria being the best understood organism to date. As a consequence, bacterial DNA repair genes encoding proteins with well characterized functions have been transferred into higher organisms in order to increase repair capacity, or to complement repair defects, in heterologous cells. While indicating the contribution of these repair functions to protection against the genotoxic effects of DNA-damaging agents, heterologous expression studies also highlighted the role of the DNA lesions that are substrates for such processes. In addition, bacterial DNA repair-like functions could be identified in higher organisms using this approach. We heterologously expressed three well characterized E. coli repair genes in S. cerevisiae cells of different genetic backgrounds: (1) the ada gene encoding O(6)-methylguanine DNA-methyltransferase, a protein involved in the repair of alkylation damage to DNA, (2) the recA gene encoding the main recombinase in E. coli and (3) the nth gene, the product of which (endonuclease III) is responsible for the repair of oxidative base damage. Here, we summarize our results and indicate the possible implications they have for a better understanding of particular DNA repair processes in S. cerevisiae.

Induction of SOS response, cellular efflux and oxidative stress response genes by chlorambucil in DNA repair-deficient Escherichia coli cells (ada, ogt and mutS)

Chlorambucil (CLB) is a bifunctional alkylating drug widely used as an anticancer agent and as an immunosuppressant. It is known to be mutagenic, teratogenic and carcinogenic. The cellular actions of CLB have remained poorly investigated. It is very likely that DNA damage and its repair are the key elements determining the destiny of CLB-exposed cells. We investigated the role of two specific DNA repair pathways involved in CLB-induced mutagenicity and gene expression changes by using Escherichia coli strains lacking either (i) two DNA methyltransferase functions (O(6)-methylguanine-DNA methyltransferase I (ada) and II (ogt)), or (ii) mismatch repair (MutS (mutS)). Mutagenicity was determined as the development of ciproxin and rifampicin resistance and the gene expression changes were assessed using expression profiling of all E. coli 4290 open reading frames (ORFs) by cDNA array. Chlorambucil-induced mutants in mutS cells, implying the importance of mismatch repair in preventing CLB-induced mutations. It also induced mutants in the ada, ogt strain, but to a lesser extent than in the wild-type strain. The simultaneous upregulation of several genes of the SOS response, cellular efflux and oxidative stress response, was demonstrated in both of the DNA repair-deficient strains but not in the wild-type cells. These and our previous results show that single-gene knock-out cells use specific gene regulation strategies to avoid mutations and cell death induced by agents such as chlorambucil.

Crystal structure of the human O(6)-alkylguanine-DNA alkyltransferase

The mutagenic and carcinogenic effects of simple alkylating agents are mainly due to O(6)-alkylation of guanine in DNA. This lesion results in transition mutations. In both prokaryotic and eukaryotic cells, repair is effected by direct reversal of the damage by a suicide protein, O(6)-alkylguanine-DNA alkyltransferase. The alkyltransferase removes the alkyl group to one of its own cysteine residues. However, this mechanism for preserving genomic integrity limits the effectiveness of certain alkylating anticancer agents. A high level of the alkyltransferase in many tumour cells renders them resistant to such drugs. Here we report the X-ray structure of the human alkyltransferase solved using the technique of multiple wavelength anomalous dispersion. This structure explains the markedly different specificities towards various O(6)-alkyl lesions and inhibitors when compared with the Escherichia coli protein (for which the structure has already been determined). It is also used to interpret the behaviour of certain mutant alkyltransferases to enhance biochemical understanding of the protein. Further examination of the various models proposed for DNA binding is also permitted. This structure may be useful for the design and refinement of drugs as chemoenhancers of alkylating agent chemotherapy.

Identification and characterisation of the Drosophila melanogaster O6-alkylguanine-DNA alkyltransferase cDNA

The protein O 6-alkylguanine-DNA alkyltransferase(alkyltransferase) is involved in the repair of O 6-alkylguanine and O 4-alkylthymine in DNA and plays an important role in most organisms in attenuating the cytotoxic and mutagenic effects of certain classes of alkylating agents. A genomic clone encompassing the Drosophila melanogaster alkyltransferase gene ( DmAGT ) was identified on the basis of sequence homology with corresponding genes in Saccharomyces cerevisiae and man. The DmAGT gene is located at position 84A on the third chromosome. The nucleotide sequence of DmAGT cDNA revealed an open reading frame encoding 194 amino acids. The MNNG-hypersensitive phenotype of alkyltransferase-deficient bacteria was rescued by expression of the DmAGT cDNA. Furthermore, alkyltransferase activity was identified in crude extracts of Escherichia coli harbouring DmAGT cDNA and this activity was inhibited by preincubation of the extract with an oligonucleotide containing a single O6-methylguanine lesion. Similar to E.coli Ogt and yeast alkyltransferase but in contrast to the human alkyltransferase, the Drosophila alkyltransferase is resistant to inactivation by O 6-benzylguanine. In an E.coli lac Z reversion assay, expression of DmAGT efficiently suppressed MNNG-induced G:C-->A:T as well as A:T-->G:C transition mutations in vivo. These results demonstrate the presence of an alkyltransferase specific for the repair of O 6-methylguanine and O 4-methylthymine in Drosophila.

Characterization of mutations that allow p-aminobenzoyl-glutamate utilization by Escherichia coli

An Escherichia coli strain deficient in p-aminobenzoate synthesis was mutagenized, and derivatives were selected for growth on folic acid. Supplementation was shown to be due to p-aminobenzoyl-glutamate present as a breakdown product in commercial folic acid preparations. Two classes of mutations characterized by the minimum concentration of p-aminobenzoyl-glutamate that could support growth were obtained. Both classes of mutations were genetically and physically mapped to about 30 min on the E. coli chromosome. A cloned wild-type gene from this region, abgT (formerly ydaH) could confer a similar p-aminobenzoyl-glutamate utilization phenotype on the parental strain. Interruption of abgT on the plasmid or on the chromosome of the mutant strain resulted in a loss of the phenotype. abgT was the third gene in an apparent operon containing abgA, abgB, abgT, and possibly ogt and might be regulated by a divergently transcribed LysR-type regulator encoded by abgR. Two different single-base-pair mutations that gave rise to the p-aminobenzoyl-glutamate utilization phenotype lay in the abgR-abgA intercistronic region and appeared to allow the expression of abgT. The second class of mutation was due to a tandem duplication of abgB and abgT fused to fnr. The abgA and abgB gene products were homologous to one another and to a family of aminoacyl aminohydrolases. p-Aminobenzoyl-glutamate hydrolysis could be detected in extracts from several of the mutant strains, but intact abgA and abgB were not essential for p-aminobenzoyl-glutamate utilization when abgT was supplied in trans.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Thermostable archaeal O6-alkylguanine-DNA alkyltransferases

Archaea represent some of the most ancient organisms on earth, and they have relatively uncharacterized DNA repair processes. We now show, using an in vitro assay, that extracts of two Crenarchaeota (Sulfolobus acidocaldarius and Pyrobaculum islandicum) and two Euryarchaeota (Pyrococcus furiosus and Thermococcus litoralis) contain the DNA repair protein O6-alkylguanine-DNA alkyltransferase (ATase). The ATase activities found in the archaea were extremely thermostable, with half-lives at 80 degreesC ranging from 0.5 hr (S. acidocaldarius) to 13 hr (T. litoralis). The temperature optima of the four proteins ranged from approximately 75 to approximately 100 degreesC, although activity was seen at 37 degreesC, the temperature optimum of the Escherichia coli and human ATases. In all cases, preincubaton of extracts with a short oligonucleotide containing a single O6-methylguanine residue caused essentially complete loss of ATase activity, suggesting that the alkylphosphotriester-DNA alkyltransferase activity seen in some prokaryotes is not present in Archaea. The ATase from Pyrobaculum islandicum had an apparent molecular mass of 15 kDa, making it the smallest of these proteins so far described. In higher organisms, ATase is responsible for the repair of toxic and mutagenic O6-alkylguanine lesions in alkylated DNA. The presence of ATase in these primitive organisms therefore suggests that endogenous or exogenous exposure to agents that generate appropriate substrates in DNA may be an early event in evolution.

New tester strains of Salmonella typhimurium lacking O6-methylguanine DNA methyltransferases and highly sensitive to mutagenic alkylating agents

Salmonella typhimurium YG7104 and YG7108 are derivatives of the Ames tester strain TA1535, and have chromosomal deletions of the ogtST gene or both the ogtST and adaST genes, respectively. The ogtST and adaST genes encode O6-methylguanine DNA methyltransferases that are involved in the repair of DNA damage caused by alkylating agents. The sensitivities of these strains to 15 mutagens with different structures were tested and compared with those of the parent strain TA1535. Deletion of ogtST or ogtST plus adaST substantially increased the sensitivity of strain TA1535 to the mutagenicity of alkylating agents, such as N-ethyl-N'-nitro-N-nitrosoguanidine, ethyl methanesulfonate or dimethylnitrosamine (DMN). Preincubation of the chemical with S9 mix and bacteria for 20 min at 37 degrees C before pouring them together on agar plates was not necessary to detect the mutagenicity of DMN when strain YG7104 or YG7108 was used as a tester strain. Introduction of plasmid pKM101 did not enhance but rather decreased the sensitivity of YG7104 and YG7108 to alkylating agents. Since the new strains are highly sensitive only to alkylating agents, they will be useful to detect the mutagenicity with high efficiency and to study the mechanism of mutagenesis induced by environmental alkylating agents.

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.

Construction and overexpression of a synthetic gene for human DNA methylguanine methyltransferase: renaturation and rapid purification of the protein

A synthetic gene was constructed that encodes human DNA methylguanine methyltransferase (hMGMT). The synthetic gene was designed with a number of unique restriction sites to facilitate cassette mutagenesis and to reflect the preferences found among genes in Escherichia coli. Both the full-length gene and a gene for a functional variant (hMGMT delta C) that lacks the C-terminal 28 codons were constructed, and the genes were overexpressed using a T7 RNA polymerase promoter. The proteins are made in the form of insoluble aggregates but the truncated form of the protein (hMGMT delta C) has been successfully denatured, renatured, and purified to near homogeneity by ion exchange. Methyltransferase activity assays of hMGMT delta C demonstrate that the reconstituted protein has substantial DNA repair activity, though somewhat less than full-length hMGMT that had been expressed and purified in a soluble form. Mass spectrometry of a mixture of proteolytic fragments confirmed the protein sequence and indicated no detectable oxidation of the active site cysteine. The protein was determined to be monomeric by gel filtration chromatography, and circular dichroism spectra for renatured hMGMT delta C and fully soluble hMGMT are consistent with the renatured protein preparation being fully folded. Refolded hMGMT delta C had a curious propensity to form large aggregates in a time-dependent manner when injected into a dynamic light scattering instrument; this aggregation behavior was not observed for hMGMT purified in a soluble form. Differences in susceptibility to aggregation may account for differences in methyltransfer activity. Yields of purified protein were approximately 5 mg/liter of culture.

Repair of O6-benzylguanine by the Escherichia coli Ada and Ogt and the human O6-alkylguanine-DNA alkyltransferases

O6-Methylguanine is removed from DNA via the transfer of the methyl group to a cysteine acceptor site present in the DNA repair protein O6-alkylguanine-DNA alkyltransferase. The human alkyltransferase is inactivated by the free base O6-benzylguanine, raising the possibility that substantially larger alkyl groups could also be accepted as substrates. However, the Escherichia coli alkyltransferase, Ada-C, is not inactivated by O6-benzylguanine. The Ada-C protein was rendered capable of reaction by the incorporation of two site-directed mutations converting Ala316 to a proline (A316P) and Trp336 to alanine (W336A) or glycine (W336G). These changes increase the space at the active site of the protein where Cys321 is buried and thus permit access of the O6-benzylguanine inhibitor. Reaction of the mutant A316P/W336A-Ada-C with O6-benzylguanine was greatly stimulated by the presence of DNA, providing strong support for the concept that binding of DNA to the Ada-C protein activates the protein. The Ada-C protein was able to repair O6-benzylguanine in a 16-mer oligodeoxyribonucleotide. However, the rate of repair was very slow, whereas the E. coli Ogt, the human alkyltransferase, and the mutant A316P/W336A-Ada-C alkyltransferases reacted very rapidly with this 16-mer substrate and preferentially repaired it when incubated with a mixture of the methylated and benzylated 16-mers. These results show that benzyl groups are better substrates than methyl groups for alkyltransferases provided that steric factors do not prevent binding of the substrate in the correct orientation for alkyl group transfer.

The influence of DNA repair by Ogt alkyltransferase on the distribution of alkylnitrosourea-induced mutations in Escherichia coli

To determine the influence of DNA repair by Ogt alkyltransferase on the distribution of alkylnitrosourea-induced mutations, we have analysed in Ogt-proficient and Ogt-deficient bacterial strains the DNA sequence changes of a total of 357 independent mutations occurring within the initial part of the lacl gene of Escherichia coli. The majority (>80%) of mutations induced by either N-ethyl-N nitrosourea (ENU) or N-methyl-N-nitrosourea (MNU) in the two genetic backgrounds were G:C --> A:T transitions, consistent with the predominant role of the O6-alkylguanine miscoding lesion in mutagenesis by alkylating agents. The analysis of the distribution of G:C --> A:T transitions induced by ENU in Ogt+ and Ogt bacteria reveals an influence of the 5'-flanking base at the level of repair by Ogt alkyltransferase. The Ogt protein appears more efficient at repairing O6-ethylguanine lesions, which are flanked 5' by a G or C, in agreement with previously reported data from our group for ethylmethane sulfonate. In contrast, no preference could be inferred for the repair of O6-methylguanine lesions by Ogt protein. These results seem to indicate that the preference of the Ogt alkyltransferase to repair certain DNA sequences might be a function of the size of the alkyl group. The importance of the alkyl group length has been described also at the level of the (A)BC excinuclease machinery that seems to have a DNA sequence specificity opposite to that of Ogt alkyltransferose.

DNA DAMAGE AND REPAIR IN PLANTS

The biological impact of any DNA damaging agent is a combined function of the chemical nature of the induced lesions and the efficiency and accuracy of their repair. Although much has been learned from microbes and mammals about both the repair of DNA damage and the biological effects of the persistence of these lesions, much remains to be learned about the mechanism and tissue-specificity of repair in plants. This review focuses on recent work on the induction and repair of DNA damage in higher plants, with special emphasis on UV-induced DNA damage products.

Binding and repair of O6-ethylguanine in double-stranded oligodeoxynucleotides by recombinant human O6-alkylguanine-DNA alkyltransferase do not exhibit significant dependence on sequence context

Double-stranded (ds) oligodeoxynucleotides (29mers) containing an O6-ethylguanine (O6-EtGua) flanked 5' and 3' by different bases (5'..TGT..3'; 5'..CGG..3', 5'..GGT..3'; 5'..GGG..3'; 5'..GGA..3') were synthesized to investigate the binding and repair characteristics of recombinant human O6-alkylguanine-DNA alkyltransferase (AT) in vitro. The apparent association constant (KA(app)) of AT to the oligomers and the repair rate constant for O6-EtGua (k) respectively, were determined by gel retardation and a monoclonal antibody-based filter binding assay. When ds- or single-stranded (ss) oligomers with or without O6-EtGua were used, no major differences in KA(app) values were observed with either substrate: KA(app) values for native AT were 7.1 and 8.4 x 10(5) M(-1) respectively, for unmodified and [O6-EtGua]-containing ds-oligomers. The corresponding values for ss-oligomers were 1.0 and 4.9 x 10(5) M(-1). The N-terminal first 56 amino acids of AT only exert a limited influence on DNA binding; the KA(app) values for an N-terminally truncated AT protein (1.1 x 10(5) M(-1)) and native AT were of the same order. Moreover, KA(app) was hardly affected by Cys(145)-methylated AT (2.0 x 10(5) M(-1)). The k-values (6.5-11.5 x 10(6) M(-1)s(-1)) were not significantly dependent on nucleotide sequence. k-values of 5.3 and 4.0 x 10(6) M(-1)s(-1) respectively, were obtained with the N-terminally truncated AT protein and for repair of the postreplicative mispair [O6-EtGua]: T by native AT. The low KA(app), the negligible influence on O6 of ethylation, and the minor modulation KA(app) and k by varying the bases flanking O6-EtGua, all indicate that the binding of AT to DNA is non-specific and mediated mainly by ionic interactions [reduced KA(app) and k-values at increased ionic strength]. Surplus DNA reduces the rate of O6-EtGua repair in ds-oligomers by competitive binding of AT molecules. The reaction mechanism of AT with DNA in vivo requires further investigation.

DNA-repair methyltransferase as a molecular device for preventing mutation and cancer

Alkylation of DNA at the 0(6) position of guanine is regarded as one o f the most critical events leading to induction of mutations and cancers in organisms. Once 0(6)-methylguanine is formed, it can pair with thymine during DNA replication, the result being a conversion of the guanine.cytosine to an adenine.thymine pair in DNA, and such mutations are often found in tumors induced by alkylating agents. To counteract such effects, organisms possess a mechanism to repair 0(6)-methylguanine in DNA. An enzyme, 0(6)-methylguanine-DNA methyltransferase, is present in various organism, from bacteria to human cells, and appears to be responsible for preventing the occurrence of such mutations. The enzyme transfers methyl groups from 0(6)-methylguanine and other methylated moieties of the DNA to its own molecule, thereby repairing DNA lesions in a single-step reaction. To elucidate the role of methyltransferase in preventing cancers, animal models with altered levels of enzyme activity were generated. Transgenic mice carrying the foreign methyltransferase gene with functional promoters had higher levels of methyltransferase activity and showed a decreased susceptibility to N-nitroso compounds in regard to liver carcinogenesis. Mouse lines deficient in the methyltransferase gene, which were established by gene targeting, exhibited an extraordinarily high sensitivity to an alkylating carcinogen.

Molecular cloning and functional analysis of a human cDNA encoding an Escherichia coli AlkB homolog, a protein involved in DNA alkylation damage repair

The Escherichia coli AlkB protein is involved in protecting cells against mutation and cell death induced specifically by SN2-type alkylating agents such as methyl methanesulfonate (MMS). A human cDNA encoding a polypeptide homologous to E.coli AlkB was discovered by searching a database of expressed sequence tags (ESTs) derived from high throughput cDNA sequencing. The full-length human AlkB homolog (hABH) cDNA clone contains a 924 bp open reading frame encoding a 34 kDa protein which is 52% similar and 23% identical to E.coli AlkB. The hABH gene, which maps to chromosome 14q24, was ubiquitously expressed in 16 human tissues examined. When hABH was expressed in E.coli alkB mutant cells partial rescue of the cells from MMS-induced cell death occurred. Under the conditions used expression of hABH in skin fibroblasts was not regulated by treatment with MMS. Our findings show that the AlkB protein is structurally and functionally conserved from bacteria to human, but its regulation may have diverged during evolution.

Role of DNA repair in resistance to drugs that alkylate O6 of guanine

The mechanism of cytotoxicity of a number of chemotherapeutic agents involves alkylation at the O6 position of guanine, a site that strongly influences cytotoxicity. Repair of these lesions by the alkyltransferase protects from cytotoxicity and is a major mechanism of resistance to these agents. O6-benzylguanine inhibition of alkyltransferase sensitizes tumor cells, and clinical trials are underway to determine its efficacy. The use of gene therapy to enhance the expression of alkyltransferase in hematopoietic cells may prevent dose-limiting myelosuppression and may enhance the utility of this class of chemotherapeutic agents.

Mutational specificity of 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea in the Escherichia coli lacl gene of O6-alkylguanine-DNA alkyltransferase-proficient and -deficient strains

Forward mutations induced by 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea (CCNU) in the lacl gene of Escherichia coli were recovered from bacteria proficient (Ogt+ Ada+) and deficient (Ogt- Ada-) in O6-alkylguanine-DNA alkyltransferase activity. A CCNU dose of 1 mM was selected for DNA sequence analysis. A total of 245 induced mutations were characterized. The mutations were almost exclusively (95%) GC-->AT transitions, indicating that CCNU-induced mutations arose in bacteria primarily from misreplication of O6-chloroethylguanine, in total agreement with results obtained for monofunctional alkylating agents. The distribution of CCNU-induced GC-->AT mutations was significantly altered by the presence of DNA alkyltransferase activity (P = 0.01). In the Ogt+ Ada+ mutational spectrum, guanines flanked on both sides by A:T base-pairs were on average 2.8 times more likely to mutate than those flanked by G:C base-pairs on at least one side. This bias disappeared in the Ogt- Ada- genetic background, thereby providing evidence that O6-chloroethylated guanines adjacent to G:C base-pairs are better targets for bacterial alkyltransferase than those not adjacent to G:C base-pairs. We recently reported a similar bias for ethyl methanesulfonate, strengthening the idea that CCNU is acting as a simple ethylating compound. In summary, this paper presents for the first time evidence that DNA repair by O6-alkylguanine-DNA alkyltransferases plays a major role in removing lesions responsible for GC-->AT transitions induced by CCNU, influencing their ultimate distribution with respect to sequence context.

Diverse capacities for the adaptive response to DNA alkylation in Bacillus species and strains

Our previous studies of Bacillus subtilis showed that the genes responsible for the adaptive response to DNA alkylation were organized as a divergent regulon, in contrast to scattered operons in Escherichia coli ada regulon. To study the generality and diversity of gene organization, several species and strains of Bacillus were examined for the responsiveness to DNA alkylation. B. cereus cells exhibited the highest resistance to MNNG treatment. When the cells were grown in the presence of MNNG, 3-methyladenine DNA glycosylase and two species of DNA methyltransferase were induced as in B. subtilis 168 cells. B. licheniformis 749 and B. amyloliquefaciens H cells exhibited a partial response that manifested itself as the induction of one species of DNA methyltransferase. On the other hand, B. thuringiensis var. Tohokuensis, B. megaterium KMT, and B. subtilis W23 cells were totally deficient in this response, and were hypersensitive to alkylating agents. To determine the cause of this deficiency in strain W23, we examined the genomic structure of the corresponding region where three genes (alkA, adaA, and adaB) were located in 168. No homologues for the three genes were detected in W23 DNA by Southern hybridization. Two genes (glmS and ndhF) flanking the adaptive response regulon in 168 were also present in W23. A sequence of about 2750 bp that carried the entire regulon in 168 was replaced with a sequence of about 250 bp that was unique to W23. At the ends of the conserved segments, palindromic sequences corresponding to the transcriptional termination sites of the adaB and glmS genes were observed. The regulon in 168 could be artificially replaced by the W23 sequence, and be regained through DNA-mediated transformation.

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.

Induction and processing of promutagenic O4-ethylthymine lesion in specific gene segments of plasmid DNA

High affinity antibodies were used for the quantitative assessment of the miscoding O4-ethylthymine (O4-EtThy) base lesion in nanogram amounts of membrane transblotted restriction fragments of ENU treated DNA. The polyclonal antibody (TB3) specifically recognized attomoles of the alkylation adducts in modified DNA with no cross-reactivity to an excess of unmodified DNA. The sensitivity of the immuno-quantitative method was determined to be in the range of 76 attomoles to 2.43 fmol, corresponding to 0.24 x 10(-7) to 7.9 x 10(-7) adducts per nucleotide in plasmid DNA. Modification levels in ras and tk genes were estimated as 0.025 and 0.014 adducts respectively. Specific antibody binding was proportional to the dose of ENU and size of the DNA fragments. In differentially ethylated ras gene, the amount of O4-EtThy was quantified as 0.026, 0.08 and 0.13 adducts per gene fragment. A DNA concentration dependent antibody binding was observed with large (23.13 and 9.41 kb) and smaller (2.02 kb) fragments of HindIII digested ENU treated phage lambda DNA. To monitor the repair of O4-EtThy lesions in specific segments, damage was assessed in sequences of plasmid DNA established in various Escherichia coli strains. The loss of antibody binding to O4-EtThy adducts in ethylated DNA fragments of 6.4 kb ras gene and 3.6 kb tk gene occurred with an approximate t1/2 of 45 and 35 min, respectively, in the repair proficient wild type E. coli. On the contrary, no repair was seen in the alkyltransferase deficient double mutant ada-ogt- strain. The results specifically demonstrate the sensitivity of the immunological technique and the unique ability of the O4-EtThy specific antibodies to scan this promutagenic base lesion and its repair in very small amounts of selected gene segments in DNA.

Response of repair-competent and repair-deficient Escherichia coli to three O6-substituted guanines and involvement of methyl-directed mismatch repair in the processing of O6-methylguanine residues

Plasmids containing a site-specifically incorporated O6-methyl- (m6G), O6-ethyl- (e6G), or O6-benzylguanine (b6G) within the ATG initiation codon of the lacZ' gene were used to transform Escherichia coli that were repair proficient or deficient in one or both of the E. coli O6-alkylguanine-DNA alkyltransferases, the uvr(ABC) excision repair system, the recA-mediated recombination system, or the methylation-directed mismatch repair system. Colonies were scored phenotypically for adduct-induced mutations. With plasmids containing either e6G or b6G, the frequency of adduct-induced mutation was low and independent of the repair proficiency of the strain transformed. Plasmids containing an m6G residue elicited similar responses in all but the mismatch repair-deficient strain. The generally low mutagenicity of all the O6-substituted guanines was interpreted as reflecting an adduct-induced arrest of replication of the modified strand while the unmodified complementary strand was replicated normally. Studies of the involvement of mismatch repair in m6G mutagenesis showed that m6G:T base pairs were more readily processed than m6G:C base pairs, indicating that mismatch repair involving m6G residues occurs after replication. These data support a model in which the E. coli methylation-directed mismatch repair system diverts plasmids containing promutagenic m6G:T base pairs into replication-arrested complexes providing another line of defense against O6-methylguanine mutagenicity in addition to O6-alkylguanine-DNA alkyltransferase repair and excision repair mechanisms.

Alkyltransferase transgenic mice: probes of chemical carcinogenesis

Transgenic mice expressing DNA-repair genes are an instructive model with which to study the protective role of DNA-repair pathways in both spontaneous and chemical carcinogenesis. Of particular interest in chemical carcinogenesis is the DNA-repair protein O6-alkylguanine-DNA alkyltransferase (alkyltransferase) which repairs O6-alkylguanine-DNA adducts. Transgenic mice carrying expression constructs for the alkyltransferase gene--either the human MGMT cDNA or the bacterial ada gene--express increased levels of alkyltransferase and have increased capacity to remove O6-methylguanine-DNA adducts. Protection from the DNA damaging effects of N-nitroso compounds occurs specifically in the cells and tissues in which the alkyltransferase transgene is expressed. For instance, mice carrying the PEPCKada construct have increased alkyltransferase in the liver and more rapid removal of O6methylguanine-DNA adducts. The protective effect is noted in hepatocytes, which express PEPCK-linked genes, not in nonparenchymal cells of the liver, which do not. Other tissues that express the transgene in the various models include the thymus, spleen, testes, muscle, stomach and brain. Mice expressing the human alkyltransferase in the thymus have a reduced incidence of thymic lymphomas following exposure to methyl nitrosourea (MNU), evidence of a role for this DNA-repair protein in protection from carcinogenesis due to N-nitroso compounds. Protection has also been observed in the induction of hepatic tumors by N-nitroso-dimethylamine (NDMA). These models will be used to identify whether overexpression of a single DNA-repair gene can block the carcinogenic process of N-nitroso compounds in many different tissues.

Requirement of the Pro-Cys-His-Arg sequence for O6-methylguanine-DNA methyltransferase activity revealed by saturation mutagenesis with negative and positive screening

O6-Methylguanine-DNA methyltransferase catalyzes transfer of a methyl group from O6-methylguanine and O4-methylthymine of DNA to a cysteine residue of the enzyme protein, thereby repairing the mutagenic and carcinogenic lesions in a single-step reaction. There are highly conserved amino acid sequences around the methyl-accepting cysteine site in eleven molecular species of methyltransferases. To elucidate the significance of the conserved sequence, amino acid substitutions were introduced by site-directed mutagenesis of the cloned DNA for Escherichia coli Ogt methyltransferase, and the activity and stability of mutant forms of the enzyme were examined. When cysteine-139, to which methyl transfer occurs, was replaced by other amino acids, all of the mutants showed the methyltransferase-negative phenotype. Methyltransferase-positive revertants, isolated from one of the negative mutants, had restored codons for cysteine. Thus the cysteine residue is essential for acceptance of the methyl group and is not replaceable by other amino acids. Using this negative and positive selection procedure, the analysis was extended to other residues near the acceptor site. At the histidine-140 and arginine-141 sites, all the positive revertants isolated carried codons for amino acids identical to those of the wild-type protein. At proline-138, five substitutions (serine, glutamine, threonine, histidine, and alanine) exhibited the positive phenotype but levels of methyltransferase activity in extracts of cells harboring these mutant forms were very low. This suggests that the proline residue at this site is important for maintaining the proper conformation of the protein. With valine-142 substitutions there were seven types of positive revertants, among which mutants carrying isoleucine, cysteine, leucine, and alanine showed relatively high levels of methyltransferase activity. These results indicate that the sequence Pro-Cys-His-Arg is a sine qua non for methyltransferase to exert its function.

Influence of DNA repair by ada and ogt alkyltransferases on the mutational specificity of alkylating agents

We investigated the influence of the alkyltransferases (ATases) encoded by the ada and ogt genes of Escherichia coli on the mutational specificity of alkylating agents. A new mutational assay for selection of supF- mutations in shuttle-vector plasmids was used. Treating plasmid-bearing bacteria with N-methyl-N-nitrosourea (MNU), N-ethyl-N-nitrosourea (ENU), and ethyl methanesulfonate (EMS) dramatically increased the mutation frequency (from 33-fold to 789-fold). The vast majority of mutations (89-100%) were G:C-->A:T transitions. This type of mutation increased in ada- (MNU) or ogt- (ENU) bacteria, suggesting that repair of O6-methylguanine by ada ATase and repair of O6-ethylguanine by ogt ATase contribute mainly to the decrease in G:C-->A:T transitions. The analysis of neighboring base sequences revealed an overabundance of G:C-->A:T transitions at 5'-GG sequences. The 5'-PuG bias increased in ATase-defective cells, suggesting that these sequences were not refractory to repair. G:C-->A:T transitions occurred preferentially in the untranscribed strand after in vivo exposure. That this strand specificity was detected even in bacteria devoid of ATase activity (ada- ogt-) and not after in vitro mutagenesis suggests a bias for damage induction rather than for DNA repair. Highly significant differences were found between the in vivo and in vitro incidences of G:C-->A:T substitutions at the two major hotspots, positions 123 (5'-GGG-3'; antisense strand) and 168 (5'-GGA-3'; sense strand). These results are explained by differences in the probability of formation of stem-loop structures in vivo and in vitro.

Effect of ogt expression on mutation induction by methyl-, ethyl- and propylmethanesulphonate in Escherichia coli K12 strains

We have previously reported the isolation of an Escherichia coli K12 mutant that is extremely sensitive to mutagenesis by low doses of ethylating agents. We now show by Southern analysis that the mutation involves a gross deletion covering at least the ogt and fnr genes and that no O6-alkylguanine-DNA-alkyltransferase activity is present in cell-free extracts of an ada::Tn10 derivative of these bacteria. Confirmation that sensitisation to ethylation-induced mutagenesis was attributable to ogt and not to any other loci covered by the deletion was obtained by constructing derivatives. Thus an ogt::kanr disruption mutation was introduced into the parental ogt+ bacteria, and the ogt::kanr mutation was then eliminated by cotransduction of ogt+ with the closely linked Tetr marker (zcj::Tn10). The delta(ogt-fnr) deletion or ogt::kanr disruption mutants were highly sensitive to ethyl methanesulphonate-induced mutagenesis, as measured by the induction of forward mutations to L-arabinose resistance (Arar). Furthermore, the number of Arar mutants increased linearly with dose, unlike the case in ogt+ bacteria, which had a threshold dose below which no mutants accumulated. Differences in mutability were even greater with propyl methanesulphonate. Overproduction of the ogt alkyltransferase from a multicopy plasmid reduced ethylmethanesulphonate-induced mutagenesis in the ogt- mutant strains and also methylmethanesulphonate mutagenesis in ada- bacteria. A sample of AB1157 obtained from the E. coli K12 genetic stock centre also had a deletion covering the ogt and fnr genes. Since such deletions greatly influence the mutagenic responses to alkylating agents, a survey of the presence of the ogt gene in the E. coli K12 strain being used is advisable.

Differential inactivation of mammalian and Escherichia coli O6-alkylguanine-DNA alkyltransferases by O6-benzylguanine

The action of O6-benzylguanine (O6-BzlG) on recombinant mammalian and Escherichia coli O6-alkylguanine-DNA alkyltransferases (ATase; EC 2.1.1.63; methylated-DNA-protein-cysteine methyltransferase) was compared by preincubation of these proteins with the base, followed by measurement of residual ATase activity using [3H]methylated substrate DNA. All of the mammalian proteins examined were inactivated by O6-BzlG (Chinese hamster: I40, 0.04 microM; human and rat: I40, 0.06 microM); however, the murine ATase was substantially more resistant requiring 4-5 fold higher concentrations of O6-BzlG to achieve the same levels of inactivation (I40, 0.28 microM). A similar differential inactivation was seen with human and murine ATases when extracts of 3T6 (murine) cells and Raji (human) cells were compared. Of the two E. coli ATase proteins, only the ogt-encoded protein was inactivated, but approximately 400 times more O6-BzlG was required to achieve a level of inactivation similar to that seen with the human protein (I40, 24.8 microM). When O6-BzlG was present in an oligonucleotide, the differential effect on the murine, human and ogt-encoded ATases was not seen and only the ada-encoded ATase remained refractory under the conditions used.