Cloning and expression in Escherichia coli of a gene for an alkylbase DNA glycosylase from Saccharomyces cerevisiae; a homologue to the bacterial alkA gene.

An alkylation repair deficient mutant of Escherichia coli (tag ada), lacking DNA glycosylase activity for removal of alkylated bases, was transformed by a genomic yeast DNA library and clones selected which survived plating on medium containing the alkylating agent methylmethane sulphonate. Three distinct yeast clones were identified which were able to suppress the alkylation sensitive phenotype of the bacterial mutant. Restriction enzyme analysis revealed common DNA fragments present in all three clones spanning 2 kb of yeast DNA. DNA from this region was sequenced and analysed for possible translation of polypeptides with any homology to either the Tag or the AlkA DNA glycosylases of E. coli. One open reading frame of 296 amino acids was identified encoding a putative protein with significant homology to AlkA. DNA containing the open reading frame was subcloned in E. coli expression vectors and cell extracts assayed for alkylbase DNA glycosylase activity. It appeared that such activity was expressed at levels sufficiently high for enzyme purification. The molecular weight of the purified protein was determined by SDS-PAGE to be 35,000 daltons, in good agreement with the 34,340 value calculated from the sequence. The yeast enzyme was able to excise 7-methylguanine as well as 3-methyladenine from dimethyl sulphate treated DNA, confirming the related nature of this enzyme to the AlkA DNA glycosylase from E. coli.     

Development of enzymatic probes of oxidative and nitrosative DNA damage caused by reactive nitrogen species

Chronic inflammation is associated with a variety of human diseases, including cancer, with one possible mechanistic link involving over-production of nitric oxide (NO*) by activated macrophages. Subsequent reaction of NO* with superoxide in the presence of carbon dioxide yields nitrosoperoxycarbonate (ONOOCO2-), a strong oxidant that reacts with guanine in DNA to form a variety of oxidation and nitration products, such 2'-deoxy-8-oxoguanosine. Alternatively, the reaction of NO and O2 leads to the formation of N2O3, a nitrosating agent that causes nucleobase deamination to form 2'-deoxyxanthosine (dX) and 2'-deoxyoxanosine (dO) from dG; 2'-deoxyinosine (dI) from dA; and 2'-deoxyuridine (dU) from dC, in addition to abasic sites and dG-dG cross-links. The presence of both ONOOCO2- and N2O3 at sites of inflammation necessitates definition of the relative roles of oxidative and nitrosative DNA damage in the genetic toxicology of inflammation. To this end, we sought to develop enzymatic probes for oxidative and nitrosative DNA lesions as a means to quantify the two types of DNA damage in in vitro DNA damage assays, such as the comet assay and as a means to differentially map the lesions in genomic DNA by the technique of ligation-mediated PCR. On the basis of fragmentary reports in the literature, we first systematically assessed the recognition of dX and dI by a battery of DNA repair enzymes. Members of the alkylpurine DNA glycosylase family (E. coli AlkA, murine Aag, and human MPG) all showed repair activity with dX (k(cat)/Km 29 x 10(-6), 21 x 10(-6), and 7.8 x 10(-6) nM(-1) min(-1), respectively), though the activity was considerably lower than that of EndoV (8 x 10(-3) nM(-1) min(-1)). Based on these results and other published studies, we focused the development of enzymatic probes on two groups of enzymes, one with activity against oxidative damage (formamidopyrimidine-DNA glycosylase (Fpg); endonuclease III (EndoIII)) and the other with activity against nucleobase deamination products (uracil DNA glycosylase (Udg); AlkA). These combinations were assessed for recognition of DNA damage caused by N2O3 (generated with a NO*/O2 delivery system) or ONOOCO2- using a plasmid nicking assay and by LC-MS analysis. Collectively, the results indicate that a combination of AlkA and Udg react selectively with DNA containing only nitrosative damage, while Fpg and EndoIII react selectively with DNA containing oxidative base lesions caused by ONOOCO2-. The results suggest that these enzyme combinations can be used as probes to define the location and quantity of the oxidative and nitrosative DNA lesions produced by chemical mediators of inflammation in systems, such as the comet assay, ligation-mediated polymerase chain reaction, and other assays of DNA damage and repair.     

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

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

Structure of a trapped endonuclease III-DNA covalent intermediate

Nearly all cells express proteins that confer resistance to the mutagenic effects of oxidative DNA damage. The primary defense against the toxicity of oxidative nucleobase lesions in DNA is the base-excision repair (BER) pathway. Endonuclease III (EndoIII) is a [4Fe-4S] cluster-containing DNA glycosylase with repair activity specific for oxidized pyrimidine lesions in duplex DNA. We have determined the crystal structure of a trapped intermediate that represents EndoIII frozen in the act of repairing DNA. The structure of the protein-DNA complex provides insight into the ability of EndoIII to recognize and repair a diverse array of oxidatively damaged bases. This structure also suggests a rationale for the frequent occurrence in certain human cancers of a specific mutation in the related DNA repair protein MYH.     

Involvement of 3-methyladenine DNA glycosylases Mag1p and Mag2p in base excision repair of methyl methanesulfonate-damaged DNA in the fission yeast Schizosaccharomyces pombe

Schizosaccharomyces pombe has two paralogues of 3-methyladenine DNA glycosylase, Mag1p and Mag2p, which share homology with Escherichia coli AlkA. To clarify the function of these redundant enzymes in base excision repair (BER) of alkylation damage, we performed several genetic analyses. The mag1 and mag2 single mutants as well as the double mutant showed no obvious methyl methanesulfonate (MMS) sensitivity. Deletion of mag1 or mag2 from an nth1 mutant resulted in tolerance to MMS damage, indicating that both enzymes generate AP sites in vivo by removal of methylated bases. A rad16 mutant that is deficient in nucleotide excision repair (NER) exhibited moderate MMS sensitivity. Deletion of mag1 from the rad16 mutant greatly enhanced MMS sensitivity, and the mag2 deletion also weakened the resistance to MMS of the rad16 mutant. A mag1/mag2/rad16 triple mutant was most sensitive to MMS. These results suggest that the NER pathway obscures the mag1 and mag2 functions in MMS resistance and that both paralogues initiate the BER pathway of MMS-induced DNA damage at the same level in NER-deficient cells or that Mag2p tends to make a little lower contribution than Mag1p. Mag1p and Mag2p functioned additively in vivo. Expression of mag1 and mag2 in the triple mutant confirmed the contribution of Mag1p and Mag2p to BER of MMS resistance.     

Fold-recognition analysis predicts that the Tag protein family shares a common domain with the helix-hairpin-helix DNA glycosylases

The Escherichia coli protein Tag is traditionally regarded as an archetype of one of four classes of N-alkylpurine DNA glycosylases. However, its structure and phylogenetic relationship to other glycosylases remains a mystery. Fold-recognition and sequence profile analyses suggest that Tag shares the catalytic domain with helix-hairpin-helix (HhH) glycosylases such as MutY, AlkA and EndoIII, but its N- and C-termini together form a unique His2Cys2 cluster. The findings presented in this paper provide insight into sequence-structure-function relationships in the Tag family and should aid in a more precise definition of the common core of the HhH superfamily of glycosylases involved in DNA repair.     

3-Methyladenine DNA glycosylase I is an unexpected helix-hairpin-helix superfamily member

The Escherichia coli enzyme 3-methyladenine DNA glycosylase I (TAG) hydrolyzes the glycosidic bond of 3-methyladenine (3-MeA) in DNA and is found in many bacteria and some higher eukaryotes. TAG shows little primary sequence identity with members of the well-known helix-hairpin-helix (HhH) superfamily of DNA repair glycosylases, which consists of AlkA, EndoIII, MutY and hOGG1. Unexpectedly, the three-dimensional solution structure reported here reveals TAG as member of this superfamily. The restricted specificity of TAG for 3-MeA bases probably arises from its unique aromatic rich 3-MeA binding pocket and the absence of a catalytic aspartate that is present in all other HhH family members.     

Excision of 8-methylguanine site-specifically incorporated into oligonucleotide substrates by the AlkA protein of Escherichia coli

8-Methyl-2'-deoxyguanosine (8-medGuo) has been shown to be a major stable alkylation product of 2'-deoxyguanosine induced by methyl radical attack on DNA. Moreover, by using primer extension assays, the latter DNA modification has recently been reported to be a miscoding lesion by generating G to C and G to T transversions and deletions in vitro. However, no data have been reported up to now, concerning the processing of this C8-alkylated nucleoside by the DNA repair machinery. Therefore, we have investigated the capability of excision of 8-methylguanine (8-meGua) site specifically incorporated into oligonucleotide substrates by several bacterial, yeast and mammalian DNA N-glycosylases. The results show that the 3-methyladenine (3-meAde) DNA glycosylase II (AlkA protein) from Escherichia coli is the only DNA N-glycosylase tested able to remove 8-meGua from double-stranded DNA fragments. Moreover, the activity of AlkA for 8-meGua varied markedly depending on the opposite base in DNA, being the highest with Adenine and Thymine and the lowest with Cytosine and Guanine. The removal of 8-meGua by AlkA protein was compared to that of 7-methylguanine (7-meGua) and hypoxanthine (Hx). The rank of damage as a substrate for AlkA being 7-meGua>8-meGua>Hx. In contrast, the human 3-meAde DNA N-glycosylase (Mpg) is not able to release 8-meGua paired with any of the four DNA bases. We also show that, DNA N-glycosylases involved in the removal of oxidative damage, such as Fpg or Nth proteins from E. coli, Ntg1, Ntg2 or Ogg1 proteins of Saccharomyces cerevisiae, or human Ogg1 do not release 8-meGua placed opposite any of the four DNA bases. Furthermore, HeLa and Chinese hamster ovary (CHO) cell free protein extracts do not show any cleavage activity at 8-meGua paired with adenine or cytosine, which suggests the absence of base excision repair (BER) of this lesion in mammalian cells.     

Kinetic mechanism for the excision of hypoxanthine by Escherichia coli AlkA and evidence for binding to DNA ends

The Escherichia coli 3-methyladenine DNA glycosylase II protein (AlkA) recognizes a broad range of oxidized and alkylated base lesions and catalyzes the hydrolysis of the N-glycosidic bond to initiate the base excision repair pathway. Although the enzyme was one of the first DNA repair glycosylases to be discovered more than 25 years ago and there are multiple crystal structures, the mechanism is poorly understood. Therefore, we have characterized the kinetic mechanism for the AlkA-catalyzed excision of the deaminated purine, hypoxanthine. The multiple-turnover glycosylase assays are consistent with Michaelis-Menten kinetics. However, under single-turnover conditions that are commonly employed for studying other DNA glycosylases, we observe an unusual biphasic protein saturation curve. Initially, the observed rate constant for excision increases with an increasing level of AlkA protein, but at higher protein concentrations, the rate constant decreases. This behavior can be most easily explained by tight binding to DNA ends and by crowding of multiple AlkA protamers on the DNA. Consistent with this model, crystal structures have shown the preferential binding of AlkA to DNA ends. By varying the position of the lesion, we identified an asymmetric substrate that does not show inhibition at higher concentrations of AlkA, and we performed pre-steady state and steady state kinetic analysis. Unlike the situation in other glycosylases, release of the abasic product is faster than N-glycosidic bond cleavage. Nevertheless, AlkA exhibits significant product inhibition under multiple-turnover conditions, and it binds approximately 10-fold more tightly to an abasic site than to a hypoxanthine lesion site. This tight binding could help protect abasic sites when the adaptive response to DNA alkylation is activated and very high levels of AlkA protein are present.     

3-methyladenine-DNA glycosylase II: the crystal structure of an AlkA-hypoxanthine complex suggests the possibility of product inhibition

Escherichia coli (E. coli) protein 3-methyladenine-DNA glycosylase II (AlkA) functions primarily by removing alkylation damage from duplex and single stranded DNA. A crystal structure of AlkA was refined to 2.0 A resolution. This structure in turn was used to refine an AlkA-hypoxanthine (substrate) complex structure to 2.4 A resolution. The complex structure shows hypoxanthine located in AlkA's active site stacked between residues W218 and Y239. The structural analysis of the AlkA and AlkA-hypoxanthine structures indicate that free hypoxanthine binding in the active site may inhibit glycosylase activity.     

Cellular repair mechanism of 5-formyluracil.

5-Formyluracil (fU) is an oxidative DNA base damage. This damage has been suggested to be mutagenic and but enzymatic repair of the damage is little known. In this study, repair enzymes that recognize fU have been studied. Kinetic analysis of the repair activity of E. coli 3-methyladenine DNA glycosylase II (AlkA) showed that fU was removed by AlkA with the efficiency comparable to 7-methylguanine. We also examined the participation of the methyl-directed mismatch repair system. The affinity of MutS to the fU:G mispair was essentially similar to that of the T:G mispair that was most efficiently recognized by the MutSLH system. These results suggest two distinct repair pathways of fU in E. coli.     

Contribution of base excision repair, nucleotide excision repair, and DNA recombination to alkylation resistance of the fission yeast Schizosaccharomyces pombe

DNA damage is unavoidable, and organisms across the evolutionary spectrum possess DNA repair pathways that are critical for cell viability and genomic stability. To understand the role of base excision repair (BER) in protecting eukaryotic cells against alkylating agents, we generated Schizosaccharomyces pombe strains mutant for the mag1 3-methyladenine DNA glycosylase gene. We report that S. pombe mag1 mutants have only a slightly increased sensitivity to methylation damage, suggesting that Mag1-initiated BER plays a surprisingly minor role in alkylation resistance in this organism. We go on to show that other DNA repair pathways play a larger role than BER in alkylation resistance. Mutations in genes involved in nucleotide excision repair (rad13) and recombinational repair (rhp51) are much more alkylation sensitive than mag1 mutants. In addition, S. pombe mutant for the flap endonuclease rad2 gene, whose precise function in DNA repair is unclear, were also more alkylation sensitive than mag1 mutants. Further, mag1 and rad13 interact synergistically for alkylation resistance, and mag1 and rhp51 display a surprisingly complex genetic interaction. A model for the role of BER in the generation of alkylation-induced DNA strand breaks in S. pombe is discussed.     

Preparation of DNA containing 7-methylguanine as unique lesions.

The predominant adduct produced by both endogenous and exogenous methylating agents is 7-methylguanine(m7G). Most studies on the repair of m7G reported so far used methylated DNA as substrates which contained other unintended lesions. In the presented study, DNA substrates containing m7G as unique lesions were prepared by DNA polymerase reactions. Using these substrates, damage recognition of E. coli 3-methyladenine DNA glycosylase II (AlkA) was analyzed. The obtained results suggested that the repair rate of m7G by AlkA was affected by the flanking sequence context of the lesion.     

The Interaction between Polynucleotide Kinase Phosphatase and the DNA Repair Protein XRCC1 Is Critical for Repair of DNA Alkylation Damage and Stable Association at DNA Damage Sites

XRCC1 plays a key role in the repair of DNA base damage and single-strand breaks. Although it has no known enzymatic activity, XRCC1 interacts with multiple DNA repair proteins and is a subunit of distinct DNA repair protein complexes. Here we used the yeast two-hybrid genetic assay to identify mutant versions of XRCC1 that are selectively defective in interacting with a single protein partner. One XRCC1 mutant, A482T, that was defective in binding to polynucleotide kinase phosphatase (PNKP) not only retained the ability to interact with partner proteins that bind to different regions of XRCC1 but also with aprataxin and aprataxin-like factor whose binding sites overlap with that of PNKP. Disruption of the interaction between PNKP and XRCC1 did not impact their initial recruitment to localized DNA damage sites but dramatically reduced their retention there. Furthermore, the interaction between PNKP and the DNA ligase IIIα-XRCC1 complex significantly increased the efficiency of reconstituted repair reactions and was required for complementation of the DNA damage sensitivity to DNA alkylation agents of xrcc1 mutant cells. Together our results reveal novel roles for the interaction between PNKP and XRCC1 in the retention of XRCC1 at DNA damage sites and in DNA alkylation damage repair.     

Biochemical characterization and DNA repair pathway interactions of Mag1-mediated base excision repair in Schizosaccharomyces pombe

The Schizosaccharomyces pombe mag1 gene encodes a DNA repair enzyme with sequence similarity to the AlkA family of DNA glycosylases, which are essential for the removal of cytotoxic alkylation products, the premutagenic deamination product hypoxanthine and certain cyclic ethenoadducts such as ethenoadenine. In this paper, we have purified the Mag1 protein and characterized its substrate specificity. It appears that the substrate range of Mag1 is limited to the major alkylation products, such as 3-mA, 3-mG and 7-mG, whereas no significant activity was found towards deamination products, ethenoadducts or oxidation products. The efficiency of 3-mA and 3-mG removal was 5–10 times slower for Mag1 than for Escherichia coli AlkA whereas the rate of 7-mG removal was similar to the two enzymes. The relatively low efficiency for the removal of cytotoxic 3-methylpurines is consistent with the moderate sensitivity of the mag1 mutant to methylating agents. Furthermore, we studied the initial steps of Mag1-dependent base excision repair (BER) and genetic interactions with other repair pathways by mutant analysis. The double mutants mag1 nth1, mag1 apn2 and mag1 rad2 displayed increased resistance to methyl methanesulfonate (MMS) compared with the single mutants nth1, apn2 and rad2, respectively, indicating that Mag1 initiates both short-patch (Nth1-dependent) and long-patch (Rad2-dependent) BER of MMS-induced damage. Spontaneous intrachromosomal recombination frequencies increased 3-fold in the mag1 mutant suggesting that Mag1 and recombinational repair (RR) are both involved in repair of alkylated bases. Finally, we show that the deletion of mag1 in the background of rad16, nth1 and rad2 single mutants reduced the total recombination frequencies of all three double mutants, indicating that abasic sites formed as a result of Mag1 removal of spontaneous base lesions are substrates for nucleotide excision repair, long- and short-patch BER and RR.     

Detection of alkylation damage in human lymphocyte DNA with the comet assay

The enzyme 3-methyladenine DNA glycosylase II (AlkA) is a bacterial repair enzyme that acts preferentially at 3-methyladenine residues in DNA, releasing the damaged base. The resulting baseless sugars are alkali-labile, and under the conditions of the alkaline comet assay (single cell gel electrophoresis) they appear as DNA strand breaks. AlkA is no t lesion-specific, but has a low activity even w ith undamagedbases. We have tested the enzyme at different concentrations to find conditions that maximise detection of alkylated bases with minimal attack on normal, undamaged DNA. AlkA detects damage in the DNA of cells treated with low concentrations of methyl methanesulphonate. We also find low background levels of alkylated bases in normal human lymphocytes.     

Endonuclease III and endonuclease VIII conditionally targeted into mitochondria enhance mitochondrial DNA repair and cell survival following oxidative stress

Mitochondrial DNA (mtDNA) is exposed to reactive oxygen species (ROS) produced during oxidative phosphorylation. Accumulation of several kinds of oxidative lesions, including oxidized pyrimidines, in mtDNA may lead to structural genomic alterations, mitochondrial dysfunction and associated degenerative diseases. In Escherichia coli, oxidative pyrimidines are repaired by endonuclease III (EndoIII) and endonuclease VIII (EndoVIII). To determine whether the overexpression of two bacterial glycosylase/AP lyases which predominantly remove oxidized pyrimidines from DNA, could improve mtDNA repair and cell survival, we constructed vectors containing sequences for the EndoIII and EndoVIII downstream of the mitochondrial targeting sequence (MTS) from manganese superoxide dismutase (MnSOD) and placed them under the control of the tetracycline (Tet)-response element. Successful integrations of MTS–EndoIII or MTS–EndoVIII into the HeLa Tet-On genome were confirmed by Southern blot. Western blots of mitochondrial extracts from MTS–EndoIII and MTS–EndoVIII clones revealed that the recombinant proteins are targeted into mitochondria and their expressions are doxycycline (Dox) dependent. Enzyme activity assays and mtDNA repair studies showed that the Dox-dependent expressions of MTS–EndoIII and MTS–EndoVIII are functional, and both MTS–EndoIII and MTS–EndoVIII (Dox+) clones were significantly more proficient at repair of oxidative damage in their mtDNA. This enhanced repair led to increased cellular resistance to oxidative stress.     

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

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

Methylpurine DNA glycosylase of the hyperthermophilic archaeon Archaeoglobus fulgidus

Base excision repair of DNA alkylation damage is initiated by a methylpurine DNA glycosylase (MPG) function. Such enzymes have previously been characterized from bacteria and eukarya, but not from archaea. We identified activity for the release of methylated bases from DNA in cell-free extracts of Archaeoglobus fulgidus, an archaeon growing optimally at 83 degrees C. An open reading frame homologous to the alkA gene of Escherichia coli was overexpressed and identified as a gene encoding an MPG enzyme (M(r) = 34 251), hereafter designated afalkA. The purified AfalkA protein differs from E. coli AlkA by excising alkylated bases only, from DNA, in the following order of efficiency: 3-methyladenine (m(3)A) > 3-methylguanine approximately 7-methyladenine > 7-methylguanine. Although the rate of enzymatic release of m(3)A is highest in the temperature range of 65-75 degrees C, it is only reduced by 50% at 45 degrees C, a temperature that does not support growth of A. fulgidus. At temperatures above 75 degrees C, nonenzymatic release of methylpurines predominates. The results suggest that the biological function of AfalkA is to excise m(3)A from DNA at suboptimal and maybe even mesophilic temperatures. This hypothesis is further supported by the observation that the afalkA gene function suppresses the alkylation sensitivity of the E. coli tag alkA double mutant. The amino acid sequence similarity and evolutionary relationship of AfalkA with other MPG enzymes from the three domains of life are described and discussed.