Reduced 5-hydroxymethyluracil-DNA glycosylase activity in Werner's syndrome cells.

Werner's syndrome (WS) is an autosomal recessive disease marked by early symptoms of accelerated aging. There is evidence indicating accumulation of oxidized DNA bases to be a major factor in cellular aging. The first step of excision repair of such bases in human cells is their removal from DNA by glycosylases. 5-Hydroxymethyluracil (HMU)-DNA glycosylase excises HMU from DNA; another glycosylase removes many non-aromatic pyrimidine derivatives. Levels of glycosylases that excise oxidized pyrimidines from DNA were compared between confluent and proliferating populations of WS cells, age-matched controls, and young control cells. They were assayed by measurements of direct release of free bases from their respective DNA substrates. Specific activities of the glycosylase that releases various modified pyrimidines and of uracil-DNA glycosylase (which removes uracil from DNA) were essentially the same in all cell lines. Cell cycle variations of these enzymes also did not differ between WS and control cells. HMU-DNA glycosylase specific activity was reduced in WS cells. Reduction of HMU-DNA glycosylase has been described in senescent human WI-38 cells. Therefore, while neither WS nor senescent cells have overall deficiencies of DNA glycosylase activities, they both might have reduced excision of HMU from DNA. This indicates a possible role of HMU accumulation in the aging process.     

Base J, found in nuclear DNA of Trypanosoma brucei, is not a target for DNA glycosylases

Base excision repair (BER) is an evolutionarily conserved system which removes altered bases from DNA. The initial step in BER is carried out by DNA glycosylases which recognize altered bases and cut the N-glycosylic bond between the base and the DNA backbone. In kinetoplastid flagellates, such as Trypanosoma brucei, the modified base beta-D-glucosyl-hydroxymethyluracil (J) replaces a small percentage of thymine residues, predominantly in repetitive telomeric sequences. Base J is synthesized at the DNA level via the precursor 5-hydroxymethyluracil (5-HmU). We have investigated whether J in DNA can be recognized by DNA glycosylases from non-kinetoplastid origin, and whether the presence of J and 5-HmU in DNA has required modifications of the trypanosome BER system. We tested the ability of 15 different DNA glycosylases from various origins to excise J or 5-HmU paired to A from duplex oligonucleotides. No excision of J was found, but 5-HmU was excised by AlkA and Mug from Escherichia coli and by human SMUG1 and TDG, confirming previous reports. In a combination of database searches and biochemical assays we identified several DNA glycosylases in T. brucei, but in trypanosome extracts we detected no excision activity towards 5-HmU or ethenocytosine, a product of oxidative DNA damage and a substrate for Mug, TDG and SMUG1. Our results indicate that trypanosomes have a BER system similar to that of other organisms, but might be unable to excise certain forms of oxidatively damaged bases. The presence of J in DNA does not require a specific modification of the BER system, as this base is not recognized by any known DNA glycosylase.     

DNA glycosylase activities for thymine residues oxidized in the methyl group are functions of the hNEIL1 and hNTH1 enzymes in human cells

Bacteria and eukaryotes possess redundant activities that recognize and remove oxidatively damaged bases from DNA through base excision repair. DNA glycosylases excise damaged bases to initiate the base excision repair pathway. hOgg1 and hNTH1, homologues of E. coli MutM and Nth, respectively, had been identified and characterized in human cells. Recent works revealed that human cells have three orthologues of E. coli Nei, hNEIL1, hNEIL2 and hNEIL3. In the present experiments, hNEIL1 protected the E. coli nth nei mutant from lethal effect of hydrogen peroxide and high frequency of spontaneous mutations under aerobic conditions. Furthermore, hNEIL1 efficiently cleaved double stranded oligonucleotides containing 5-formyluracil (5-foU) and 5-hydroxymethyluracil (5-hmU) in vitro via beta- and delta-elimination reactions. Similar activities were detected with hNTH1. These results indicate that hNEIL1 and hNTH1 are DNA glycosylases that excise 5-foU and 5-hmU as efficiently as Tg in human cells.     

Compromised incision of oxidized pyrimidines in liver mitochondria of mice deficient in NTH1 and OGG1 glycosylases

Mitochondrial DNA is constantly exposed to high levels of endogenously produced reactive oxygen species, resulting in elevated levels of oxidative damaged DNA bases. A large spectrum of DNA base alterations can be detected after oxidative stress, and many of these are highly mutagenic. Thus, an efficient repair of these is necessary for survival. Some of the DNA repair pathways involved have been characterized, but others are not yet determined. A DNA repair activity for thymine glycol and other oxidized pyrimidines has been described in mammalian mitochondria, but the nature of the glycosylases involved in this pathway remains unclear. The generation of mouse strains lacking murine thymine glycol-DNA glycosylase (mNTH1) and/or murine 8-oxoguanine-DNA glycosylase (mOGG1), the two major DNA N-glycosylase/apurinic/apyrimidinic (AP) lyases involved in the repair of oxidative base damage in the nucleus, has provided very useful biological model systems for the study of the function of these and other glycosylases in mitochondrial DNA repair. In this study, mouse liver mitochondrial extracts were generated from mNTH1-, mOGG1-, and [mNTH1, mOGG1]-deficient mice to ascertain the role of each of these glycosylases in the repair of oxidized pyrimidine base damage. We also characterized for the first time the incision of various modified bases in mitochondrial extracts from a double-knock-out [mNTH1, mOGG1]-deficient mouse. We show that mNTH1 is responsible for the repair of thymine glycols in mitochondrial DNA, whereas other glycosylase/AP lyases also participate in removing other oxidized pyrimidines, such as 5-hydroxycytosine and 5-hydroxyuracil. We did not detect a backup glycosylase or glycosylase/AP lyase activity for thymine glycol in the mitochondrial mouse extracts.     

Structural and functional properties of CiNTH, an endonuclease III homologue of the ascidian Ciona intestinalis: critical role of N-terminal region

Oxidatively damaged bases in DNA can cause cell death, mutation and/or cancer induction. To overcome such deleterious effects of DNA base oxidation, cells are equipped with base excision repair (BER) initiated by DNA glycosylases. Endonuclease III (Nth), a major DNA glycosylase, mainly excises oxidatively damaged pyrimidines from DNA. The aims of this study were to obtain an overview of the repair mechanism of oxidatively damaged bases and to elucidate the function of BER in maintaining genome stability during embryogenesis and development. In this study, we used the ascidian Ciona intestinalis because at every developmental stage it is possible to observe the phenotype of individuals with DNA damage or mutations. Sequence alignment analysis revealed that the amino acid sequence of Ciona intestinalis Nth homologue (CiNTH) had high homology with those of Escherichia coli, Saccharomyces cerevisiae, Schizosaccharomyces pombe, Caenorhabditis elegans and human Nth homologues. It was evident that two domains, the Helix-hairpin-Helix and 4Fe-4S cluster domains that are critical regions for the Nth activity, are well conserved in CiNTH. CiNTH efficiently complemented the sensitivity of E. coli nth nei mutant to H(2)O(2). CiNTH was bifunctional, with DNA glycosylase and AP lyase activities. It removed thymine glycol, 5-formyluracil and 8-oxoguanine paired with G from DNA via a β-elimination reaction. Interestingly, the N-terminal 44 amino acids were essential for the DNA glycosylase activity of CiNTH.     

Repair of deaminated bases in DNA

Deamination of DNA bases can occur spontaneously, generating highly mutagenic lesions such as uracil, hypoxanthine, and xanthine. When cells are under oxidative stress that is induced either by oxidizing agents or by mitochondrial dysfunction, additional deamination products such as 5-hydroxymethyluracil (5-HMU) and 5-hydroxyuracil (5-OH-Ura) are formed. The cellular level of these highly mutagenic lesions is increased substantially when cells are exposed to DNA damaging agent, such as ionizing radiation, redox reagents, nitric oxide, and others. The cellular repair of deamination products is predominantly through the base excision repair (BER) pathway, a major cellular repair pathway that is initiated by lesion specific DNA glycosylases. In BER, the lesions are removed by the combined action of a DNA glycosylase and an AP endonuclease, leaving behind a one-base gap. The gapped product is then further repaired by the sequential action of DNA polymerase and DNA ligase. DNA glycosylases that recognize uracil, 5-OH-Ura, 5-HMU (derived from 5-methylcytosine) and a T/G mismatch (derived from a 5-methylcytosine/G pair) are present in most cells. Many of these glycosylases have been cloned and well characterized. In yeast and mammalian cells, hypoxanthine is efficiently removed by methylpurine N-glycosylase, and it is thought that BER might be an important pathway for the repair of hypoxanthine. In contrast, no glycosylase that can recognize xanthine has been identified in either yeast or mammalian cells. In Escherichia coli, the major enzyme activity that initiates the repair of hypoxanthine and xanthine is endonuclease V. Endonuclease V is an endonuclease that hydrolyzes the second phosphodiester bond 3' to the lesion. It is hypothesized that the cleaved DNA is further repaired through an alternative excision repair (AER) pathway that requires the participation of either a 5' endonuclease or a 3'-5' exonuclease to remove the damaged base. The repair process is then completed by the sequential actions of DNA polymerase and DNA ligase. Endonuclease V sequence homologs are present in all kingdoms, and it is conceivable that endonuclease V might also be a major enzyme that initiates the repair of hypoxanthine and xanthine in mammalian cells.     

Crystal structures of 3-methyladenine DNA glycosylase MagIII and the recognition of alkylated bases

DNA glycosylases catalyze the excision of chemically modified bases from DNA. Although most glycosylases are specific to a particular base, the 3-methyladenine (m3A) DNA glycosylases include both highly specific enzymes acting on a single modified base, and enzymes with broader specificity for alkylation-damaged DNA. Our structural understanding of these different enzymatic specificities is currently limited to crystal and NMR structures of the unliganded enzymes and complexes with abasic DNA inhibitors. Presented here are high-resolution crystal structures of the m3A DNA glycosylase from Helicobacter pylori (MagIII) in the unliganded form and bound to alkylated bases 3,9-dimethyladenine and 1,N6-ethenoadenine. These are the first structures of a nucleobase bound in the active site of a m3A glycosylase belonging to the helix-hairpin-helix superfamily. MagIII achieves its specificity for positively-charged m3A not by direct interactions with purine or methyl substituent atoms, but rather by stacking the base between two aromatic side chains in a pocket that excludes 7-methylguanine. We report base excision and DNA binding activities of MagIII active site mutants, together with a structural comparison of the HhH glycosylases.     

XRCC1 interactions with multiple DNA glycosylases: a model for its recruitment to base excision repair

Repair of chemically modified bases in DNA is accomplished through base excision repair (BER). This pathway is initiated by a specific DNA glycosylase that recognizes and excises the altered base to yield an abasic (AP) site. After cleavage of the AP site by APE1, repair proceeds through re-synthesis and ligation steps. In mammalian cells, the XRCC1 protein, essential for the maintenance of genomic stability, is involved in both base excision and single-strand break repair. XRCC1 participates in the first step of BER by interacting with the human DNA glycosylases hOGG1 and NEIL1. To analyze the possibility of a general mechanism involving the interaction of XRCC1 with DNA glycosylases we used XRCC1 to pull-down DNA glycosylases activities from human cell extracts. XRCC1 co-purifies with DNA glycosylase activities capable of excising hypoxanthine and dihydrothymine, in addition to 8-oxoguanine, but not uracil. Biochemical analyses with the purified proteins confirmed the interactions between XRCC1 and MPG, hNTH1 or hNEIL2. Furthermore, XRCC1 stimulates the activities of these enzymes. In vivo localization studies show that after genotoxic treatments these DNA glycosylases can be found associated with XRCC1 foci. Our results support a BER model in which XRCC1 is recruited to the repair of alkylated or oxidized bases by the enzyme recognizing the lesion. XRCC1 would then coordinate the subsequent enzymatic steps and modulate the activities of all the proteins involved.     

Excision of cytosine and thymine from DNA by mutants of human uracil-DNA glycosylase.

Uracil-DNA glycosylase (UDG) protects the genome by removing mutagenic uracil residues resulting from deamination of cytosine. Uracil binds in a rigid pocket at the base of the DNA-binding groove of human UDG and the specificity for uracil over the structurally related DNA bases thymine and cytosine is conferred by shape complementarity, as well as by main chain and Asn204 side chain hydrogen bonds. Here we show that replacement of Asn204 by Asp or Tyr147 by Ala, Cys or Ser results in enzymes that have cytosine-DNA glycosylase (CDG) activity or thymine-DNA glycosylase (TDG) activity, respectively. CDG and the TDG all retain some UDG activity. CDG and TDG have kcat values in the same range as typical multisubstrate-DNA glycosylases, that is at least three orders of magnitude lower than that of the highly selective and efficient wild-type UDG. Expression of CDG or TDG in Escherichia coli causes 4- to 100-fold increases in the yield of rifampicin-resistant mutants. Thus, single amino acid substitutions in UDG result in less selective DNA glycosylases that release normal pyrimidines and confer a mutator phenotype upon the cell. Three of the four new pyrimidine-DNA glycosylases resulted from single nucleotide substitutions, events that may also happen in vivo.     

Plant and fungal Fpg homologs are formamidopyrimidine DNA glycosylases but not 8-oxoguanine DNA glycosylases

Formamidopyrimidine DNA glycosylase (Fpg) and endonuclease VIII (Nei) share an overall common three-dimensional structure and primary amino acid sequence in conserved structural motifs but have different substrate specificities, with bacterial Fpg proteins recognizing formamidopyrimidines, 8-oxoguanine (8-oxoG) and its oxidation products guanidinohydantoin (Gh), and spiroiminodihydantoin (Sp) and bacterial Nei proteins recognizing primarily damaged pyrimidines. In addition to bacteria, Fpg has also been found in plants, while Nei is sparsely distributed among the prokaryotes and eukaryotes. Phylogenetic analysis of Fpg and Nei DNA glycosylases demonstrated, with 95% bootstrap support, a clade containing exclusively sequences from plants and fungi. Members of this clade exhibit sequence features closer to bacterial Fpg proteins than to any protein designated as Nei based on biochemical studies. The Candida albicans (Cal) Fpg DNA glycosylase and a previously studied Arabidopsis thaliana (Ath) Fpg DNA glycosylase were expressed, purified and characterized. In oligodeoxynucleotides, the preferred glycosylase substrates for both enzymes were Gh and Sp, the oxidation products of 8-oxoG, with the best substrate being a site of base loss. GC/MS analysis of bases released from γ-irradiated DNA show FapyAde and FapyGua to be excellent substrates as well. Studies carried out with oligodeoxynucleotide substrates demonstrate that both enzymes discriminated against A opposite the base lesion, characteristic of Fpg glycosylases. Single turnover kinetics with oligodeoxynucleotides showed that the plant and fungal glycosylases were most active on Gh and Sp, less active on oxidized pyrimidines and exhibited very little or no activity on 8-oxoG. Surprisingly, the activity of AthFpg1 on an AP site opposite a G was extremely robust with a k_obs of over 2500 min^?1.     

Purification and characterization of 5-hydroxymethyluracil-DNA glycosylase from calf thymus. Its possible role in the maintenance of methylated cytosine residues

5-Hydroxymethyluracil (HmUra) residues formed by the oxidation of thymine are removed from DNA through the action of a DNA glycosylase activity. This activity was purified over 1870-fold from calf thymus and found to be distinct from uracil (Ura)-DNA glycosylase. The HmUra-DNA glycosylase has a molecular weight of 38,000, a pH optimum of 6.7-6.8 and an apparent Km of 0.73 +/- 0.04 microM. These values are similar to those reported for other mammalian DNA glycosylases. The enzyme removed HmUra residues from single- and double-stranded DNA with almost equal efficiency. HmUra-DNA glycosylase activity was not product inhibited by free HmUra. The DNA glycosylase activity was inhibited by Mg2+, but the purest enzyme fractions contained a Mg2+-dependent apurinic/apyrimidinic endonuclease activity. HmUra-DNA glycosylase and the recently described 5-hydroxymethylcytosine (HmCyt)-DNA glycosylase (Cannon, S. V., Cummings, A. C., and Teebor, G. W. (1988) Biochem. Biophys. Res. Commun. 151, 1173-1179) are unique among known DNA glycosylases in being present in mammalian cells and absent from bacteria. These DNA glycosylase activities were shown here to reside on different proteins. We suggest that the major function of HmUra-DNA glycosylase, together with HmCyt-DNA glycosylase, is the maintenance of methylated cytosine residues in the DNA of higher organisms.     

5-Hydroxymethylcytosine DNA glycosylase activity in mammalian tissue

The enzymatic release of 5-hydroxymethylcytosine from T2 bacteriophage DNA was effected by an extract of calf thymus. Like the previously described 5-hydroxymethyluracil DNA glycosylase, 5-hydroxymethylcytosine DNA glycosylase was not detectable in bacterial extracts. The phylogenetic distribution of these activities indicates that their primary function is the maintenance of methylcytosine residues in differentiated tissue.     

Modulation of DNA glycosylase activities in mesenchymal stem cells

Adipose-tissue derived mesenchymal stem cells (AT-MSCs) are a promising tool for use in cell-based therapies. However, in vitro expansion is required to obtain clinically relevant cell numbers, and this might increase the chance of genomic instability. DNA repair is crucial for maintaining DNA integrity. Here we have compared the initial step of base excision repair in uncultured and cultured AT-MSCs by analysis of base removal activities and expression levels of relevant DNA glycosylases. Uracil, 5-hydroxyuracil and ethenoadenine removal activities were upregulated in cultured cells compared to uncultured cells. In contrast, both the 8-oxo-7,8-dihydroguanine (8-oxoG) removal activity and the concentration of 8-oxoG bases in the DNA were reduced in the cultured cells. Gene expression analysis showed no substantial changes in mRNA expression. The glycosylase activities remained stable through at least 12 passages, suggesting that DNA repair is proficient through the period required for in vitro expansion of AT-MSCs to clinically relevant numbers.     

Identification of high excision capacity for 5-hydroxymethyluracil mispaired with guanine in DNA of Escherichia coli MutM,Nei and Nth DNA glycosylases

The oxidation and deamination of 5-methylcytosine (5mC) in DNA generates a base-pair between 5-hydroxymethyluracil (5hmU) and guanine. 5hmU normally forms a base-pair with adenine. Therefore, the conversion of 5mC to 5hmU is a potential pathway for the generation of 5mC to T transitions. Mammalian cells have high levels of activity of 5hmU-DNA glycosylase, which excises 5hmU from DNA. However, glycosylases that similarly excise 5hmU have not been observed in yeast or Escherichia coli. Recently, we found that E.coli MutM, Nei and Nth have DNA glycosylase activity for 5-formyluracil, which is another type of oxidation product of the thymine methyl group. In this study, we examined whether or not E.coli MutM, Nei and Nth have also DNA glycosylase activity that acts on 5hmU in vitro. When incubated with synthetic duplex oligonucleotides containing 5hmU:G or 5hmU:A, purified MutM, Nei and Nth cleaved the 5hmU:G oligonucleotide 58, 5 and 37 times, respectively, more efficiently than the 5hmU:A oligonucleotide. In E.coli, the 5hmU-DNA glycosylase activities of MutM, Nei and Nth may play critical roles in the repair of 5hmU:G mispairs to avoid 5mC to T transitions.     

Mammalian 5-formyluracil-DNA glycosylase. 2. Role of SMUG1 uracil-DNA glycosylase in repair of 5-formyluracil and other oxidized and deaminated base lesions

In the accompanying paper [Matsubara, M., et al. (2003) Biochemistry 42, 4993-5002], we have partially purified and characterized rat 5-formyluracil (fU)-DNA glycosylase (FDG). Several lines of evidence have indicated that FDG is a rat homologue of single-strand-selective monofunctional uracil-DNA glycosylase (SMUG1). We report here that rat and human SMUG1 (rSMUG1 and hSMUG1) expressed from the corresponding cDNAs indeed excise fU in single-stranded (ss) and double-stranded (ds) DNA. The enzymes also excised uracil (U) and uracil derivatives bearing an oxidized group at C5 [5-hydroxyuracil (hoU) and 5-hydroxymethyluracil (hmU)] in ssDNA and dsDNA but not analogous cytosine derivatives (5-hydroxycytosine and 5-formylcytosine) and other oxidized damage. The damage specificity and the salt concentration dependence of rSMUG1 (and hSMUG1) agreed well with those of FDG, confirming that FDG is rSMUG1. Consistent with the damage specificity above, hSMUG1 removed damaged bases from Fenton-oxidized calf thymus DNA, generating abasic sites. The amount of resulting abasic sites was about 10% of that generated by endonuclease III or 8-oxoguanine glycosylase in the same substrate. The HeLa cell extract and hSMUG1 exhibited a similar damage preference (hoU.G > hmU.A, fU.A), and the activities for fU, hmU, and hoU in the cell extract were effectively neutralized with hSMUG1 antibodies. These data indicate a dual role of hSMUG1 as a backup enzyme for UNG and a primary repair enzyme for a subset of oxidized pyrimidines such as fU, hmU, and hoU.     

Human endonuclease VIII-like (NEIL) proteins in the giant DNA Mimivirus

Endonuclease VIII (Nei), which recognizes and repairs oxidized pyrimidines in the base excision repair (BER) pathway, is sparsely distributed among both the prokaryotes and eukaryotes. Recently, we and others identified three homologs of Escherichia coli endonuclease VIII-like (NEIL) proteins in humans. Here, we report identification of human NEIL homologs in Mimivirus, a giant DNA virus that infects Acanthamoeba. Characterization of the two mimiviral homologs, MvNei1 and MvNei2, showed that they share not only sequence homology but also substrate specificity with the human NEIL proteins, that is, they recognize oxidized pyrimidines in duplex DNA and in bubble substrates and as well show 5'2-deoxyribose-5-phosphate lyase (dRP lyase) activity. However, unlike MvNei1 and the human NEIL proteins, MvNei2 preferentially cleaves oxidized pyrimidines in single stranded DNA forming products with a different end chemistry. Interestingly, opposite base specificity of MvNei1 resembles human NEIL proteins for pyrimidine base damages whereas it resembles E. coli formamidopyrimidine DNA glycosylase (Fpg) for guanidinohydantoin (Gh), an oxidation product of 8-oxoguanine. Finally, a conserved arginine residue in the "zincless finger" motif, previously identified in human NEIL1, is required for the DNA glycosylase activity of MvNei1. Thus, Mimivirus represents the first example of a virus to carry oxidative DNA glycosylases with substrate specificities that resemble human NEIL proteins. Based on the sequence homology to the human NEIL homologs and novel bacterial NEIL homologs identified here, we predict that Mimivirus may have acquired the DNA glycosylases through the host-mediated lateral transfer from either a bacterium or from vertebrates.     

Oxanine DNA glycosylase activities in mammalian systems

DNA bases carrying an exocyclic amino group, namely adenine (A), guanine (G) and cytosine (C), encounter deamination under nitrosative stress. Oxanine (O), derived from deamination of guanine, is a cytotoxic and potentially mutagenic lesion and studies of its enzymatic repair are limited. Previously, we reported that the murine alkyladenine glycosylase (Aag) acts as an oxanine DNA glycosylase (JBC (2004), 279: 38177). Here, we report our recent findings on additional oxanine DNA glycosylase (ODG) activities in Aag knockout mouse tissues and other mammalian tissues. Analysis of the partially purified proteins from the mammalian cell extracts indicated the existence of ODG enzymes in addition to Aag. Data obtained from oxanine DNA cleavage assays using purified human glycosylases demonstrated that two known glycosylases, hNEIL1 and hSMUG1, contained weak but detectable ODG activities. ODG activity was the highest in hAAG and lowest in hSMUG1.     

Inhibition of DNA repair glycosylases by base analogs and tryptophan pyrolysate, Trp-P-1

DNA base analogs, 2,4,5,6-substituted pyrimidines and 2,6-substituted purines were tested as potential inhibitors of E. coli Fpg protein (formamidopyrimidine -DNA glycosylase). Three of the seventeen compounds tested revealed inhibitory properties. 2-Thioxanthine was the most efficient, inhibiting 50% of 2,6-diamino-4-hydroxy-5N-methyl-formamidopyrimidine (Fapy-7MeG) excision activity at 17.1 microM concentration. The measured K(i) was 4.44 +/- 0.15 microM. Inhibition was observed only when the Fpg protein was first challenged to its substrate followed by the addition of the base analog, suggesting uncompetitive (catalytic) inhibition. For two other compounds, 2-thio- or 2-oxo-4,5,6-substituted pyrimidines, IC(50) was only 343.3 +/- 58.6 and 350 +/- 24.4 microM, respectively. No change of the Fpg glycosylase activity was detected in the presence of Fapy-7MeG, up to 5 microM. We also investigated the effect of DNA structure modified by tryptophan pyrolysate (Trp-P-1) on the activity of base excision repair enzymes: Escherichia coli and human DNA glycosylases of oxidized (Fpg, Nth) and alkylated bases (TagA, AlkA, and ANPG), and for bacterial AP endonuclease (Xth protein). Trp-P-1, which changes the secondary DNA structure into non-B, non-Z most efficiently inhibited excision of alkylated bases by the AlkA glycosylase (IC(50) = 1 microM). The ANPG, TagA, and Fpg proteins were also inhibited although to a lesser extent (IC(50) = 76.5 microM, 96 microM, and 187.5 microM, respectively). Trp-P-1 also inhibited incision of DNA at abasic sites by the beta-lyase activity of the Fpg and Nth proteins, and to a lesser extent by the Xth AP endonuclease. Thus, DNA conformation is critical for excision of damaged bases and incision of abasic sites by DNA repair enzymes.     

An evolutionary analysis of the helix-hairpin-helix superfamily of DNA repair glycosylases

The helix-hairpin-helix (HhH) superfamily of base excision repair DNA glycosylases is composed of multiple phylogenetically diverse enzymes that are capable of excising varying spectra of oxidatively and methyl-damaged bases. Although these DNA repair glycosylases have been widely studied through genetic, biochemical, and biophysical approaches, the evolutionary relationships of different HhH homologs and the extent to which they are conserved across phylogeny remain enigmatic. We provide an evolutionary framework for this pervasive and versatile superfamily of DNA glycosylases. Six HhH gene families (named AlkA: alkyladenine glycosylase; MpgII: N-methylpurine glycosylase II; MutY/Mig: A/G-specific adenine glycosylase/mismatch glycosylase; Nth: endonuclease III; OggI: 8-oxoguanine glycosylase I; and OggII: 8-oxoguanine glycosylase II) are identified through phylogenetic analysis of 234 homologs found in 94 genomes (16 archaea, 64 bacteria, and 14 eukaryotes). The number of homologs in each gene family varies from 117 in the Nth family (nearly every genome surveyed harbors at least one Nth homolog) to only five in the divergent OggII family (all from archaeal genomes). Sequences from all three domains of life are included in four of the six gene families, suggesting that the HhH superfamily diversified very early in evolution. The phylogeny provides evidence for multiple lineage-specific gene duplication events, most of which involve eukaryotic homologs in the Nth and AlkA gene families. We observe extensive variation in the number of HhH superfamily glycosylase genes present in different genomes, possibly reflecting major differences among species in the mechanisms and pathways by which damaged bases are repaired and/or disparities in the basic rates and spectra of mutation experienced by different genomes.     

Repair of the mutagenic DNA oxidation product, 5-formyluracil

The oxidation of the thymine methyl group can generate 5-formyluracil (FoU). Template FoU residues are known to miscode, generating base substitution mutations. The repair of the FoU lesion is therefore important in minimizing mutations induced by DNA oxidation. We have studied the repair of FoU in synthetic oligonucleotides when paired with A and G. In E. coli cell extract, the repair of FoU is four orders of magnitude lower than the repair of U and is similar for both FoU:A and FoU:G base pairs. In HeLa nuclear extract, the repair of FoU:A is similarly four orders of magnitude lower than the repair of uracil, although the FoU:G lesion is repaired 10 times more efficiently than FoU:A. The FoU:G lesion is shown to be repaired by E. coli mismatch uracil DNA glycosylase (Mug), thermophile mismatch thymine DNA glycosylase (Tdg), mouse mismatch thymine DNA glycosylase (mTDG) and human methyl-CpG-binding thymine DNA glycosylase (MBD4), whereas the FoU:A lesion is repaired only by Mug and mTDG. The repair of FoU relative to the other pyrimidines examined here in human cell extract differs from the substrate preferences of the known glycosylases, suggesting that additional, and as yet unidentified glycosylases exist in human cells to repair the FoU lesion. Indeed, as observed in HeLa nuclear extract, the repair of mispaired FoU derived from misincorporation of dGMP across from template FoU could promote rather than minimize mutagenesis. The pathways by which this important lesion is repaired in human cells are as yet unexplained, and are likely to be complex.