Mechanism of action of base release by Escherichia coli Fpg protein: role of lysine 155 in catalysis

α-Amidoamids as New Replacements of Antibiotics-Research on the Chosen K12, R2-R4 E. coli Strains

A preliminary study of α-amidoamids as new potential antimicrobial drugs was performed. Special emphasis was placed on selection of structure of α-amidoamids with the highest biological activity against different types of Gram-stained bacteria by lipopolysaccharide (LPS). Herein, Escherichia coli model strains K12 (without LPS in its structure) and R1-R4 (with different length LPS in its structure) were used. The presented work showed that the antibacterial activity of α-amidoamids depends on their structure and affects the LPS of bacteria. Moreover, the influence of various newly synthesized α-amidoamids on bacteria possessing smooth and rought LPS and oxidative damage of plasmid DNA caused by all newly obtained compounds was indicated. The presented studies clearly explain that α-amidoamids can be used as substitutes for antibiotics. The chemical and biological activity of the analysed α-amidoamids was associated with short alkyl chain and different isocyanides molecules in their structure such as: tetr-butyl isocyanide or 2,5-dimethoxybenzyl isocyanide. The observed results are especially important in the case of the increasing resistance of bacteria to various drugs and antibiotics.

Molecular dynamics simulation of the opposite-base preference and interactions in the active site of formamidopyrimidine-DNA glycosylase

Background

Formamidopyrimidine-DNA glycosylase (Fpg) removes abundant pre-mutagenic 8-oxoguanine (oxoG) bases from DNA through nucleophilic attack of its N-terminal proline at C1′ of the damaged nucleotide. Since oxoG efficiently pairs with both C and A, Fpg must excise oxoG from pairs with C but not with A, otherwise a mutation occurs. The crystal structures of several Fpg–DNA complexes have been solved, yet no structure with A opposite the lesion is available.

Results

Here we use molecular dynamic simulation to model interactions in the pre-catalytic complex of Lactococcus lactis Fpg with DNA containing oxoG opposite C or A, the latter in either syn or anti conformation. The catalytic dyad, Pro1–Glu2, was modeled in all four possible protonation states. Only one transition was observed in the experimental reaction rate pH dependence plots, and Glu2 kept the same set of interactions regardless of its protonation state, suggesting that it does not limit the reaction rate. The adenine base opposite oxoG was highly distorting for the adjacent nucleotides: in the more stable syn models it formed non-canonical bonds with out-of-register nucleotides in both the damaged and the complementary strand, whereas in the anti models the adenine either formed non-canonical bonds or was expelled into the major groove. The side chains of Arg109 and Phe111 that Fpg inserts into DNA to maintain its kinked conformation tended to withdraw from their positions if A was opposite to the lesion. The region showing the largest differences in the dynamics between oxoG:C and oxoG:A substrates was unexpectedly remote from the active site, located near the linker joining the two domains of Fpg. This region was also highly conserved among 124 analyzed Fpg sequences. Three sites trapping water molecules through multiple bonds were identified on the protein–DNA interface, apparently helping to maintain enzyme-induced DNA distortion and participating in oxoG recognition.

Conclusion

Overall, the discrimination against A opposite to the lesion seems to be due to incorrect DNA distortion around the lesion-containing base pair and, possibly, to gross movement of protein domains connected by the linker.

Electronic supplementary material

The online version of this article (doi:10.1186/s12900-017-0075-y) contains supplementary material, which is available to authorized users.

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.

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.

Surprising repair activities of nonpolar analogs of 8-oxoG expose features of recognition and catalysis by base excision repair glycosylases

Repair glycosylases locate and excise damaged bases from DNA, playing central roles in preservation of the genome and prevention of disease. Two key glycosylases, Fpg and hOGG1, function to remove the mutagenic oxidized base 8-oxoG (OG) from DNA. To investigate the relative contributions of conformational preferences, leaving group ability, enzyme-base hydrogen bonding, and nucleobase shape on damage recognition by these glycosylases, a series of four substituted indole nucleosides, based on the parent OG nonpolar isostere 2Cl-4F-indole, were tested as possible direct substrates of these enzymes in the context of 30 base pair duplexes paired with C. Surprisingly, single-turnover experiments revealed that Fpg-catalyzed base removal activity of two of the nonpolar analogs was superior to the native OG substrate. The hOGG1 glycosylase was also found to catalyze removal of three of the nonpolar analogs, albeit considerably less efficiently than removal of OG. Of note, the analog that was completely resistant to hOGG1-catalyzed excision has a chloro-substituent at the position of NH7 of OG, implicating the importance of recognition of this position in catalysis. Both hOGG1 and Fpg retained high affinity for the duplexes containing the nonpolar isosteres. These studies show that hydrogen bonds between base and enzyme are not needed for efficient damage recognition and repair by Fpg and underscore the importance of facile extrusion from the helix in its damaged base selection. In contrast, damage removal by hOGG1 is sensitive to both hydrogen bonding groups and nucleobase shape. The relative rates of excision of the analogs with the two glycosylases highlight key differences in their mechanisms of damaged base recognition and removal.

Effects of nucleophile, oxidative damage, and nucleobase orientation on the glycosidic bond cleavage in deoxyguanosine

Deglycosylation of nucleotides occurs during many essential biological processes, including DNA repair, and is initiated by a variety of nucleophiles. In the present work, density functional theory (B3LYP) was used to investigate the thermodynamics and kinetics of the glycosidic bond cleavage reaction in the model nucleoside forms of guanine and its major oxidation product, 8-oxoguanine. Base excision facilitated by four different nucleophiles (hydroxyl anion (fully activated water), formate-water complex (partially activated water), lysine, and proline) was considered, which spans nucleophiles involved in a collection of spontaneous and enzyme-catalyzed processes. Because some enzymes that catalyze deglycosylation can accommodate more than one orientation of the base with respect to the sugar moiety, the effects of the (anti/syn) base orientation on the barrier height were also considered. We find that the nucleophile has a very large effect on the overall (gas-phase) reaction energetics. Although this effect decreases in different (polar) environments, the nucleophile has the greatest influence on the overall reaction as compared to whether the base is damaged or to the base orientation. Furthermore, the effects are significant in environments that most closely resemble (nonpolar) enzymatic active sites. Our results provide a greater understanding of the relative effects of the nucleophile, damage to the nucleobase, and the nucleobase orientation with respect to the sugar moiety on the deglycosylation pathway, which provide qualitative explanations for relative base excision rates observed in some biological systems.

Glycosidic bond cleavage in deoxynucleotides — A density functional study

Density functional theory was used to study the glycosidic bond cleavage in deoxynucleotides with the main goal to determine the effects of the nucleobase, hydrogen bonding with the nucleobase, and the (bulk) environment on the reaction energetics. Since direct glycosidic bond cleavage is a high-energy process, two nucleophile models were considered (HCOO–···H2O and HO–), which represent different stages of activation of a water nucleophile. The glycosidic bond cleavage barriers were found to decrease, while the reaction exothermicity increases, with an increase in the nucleobase acidity. The gas-phase barriers and reaction energies for bond cleavage in all deoxynucleotides were found to be significantly affected by hydrogen-bonding interactions with the nucleobase (by up to 30 kJ mol–1 depending on the nucleophile). Although the barriers increase and reaction energies become less exothermic in enzymatic and aqueous environments, the effects of the bulk environment are similar in the presence and absence of small molecules bound to the nucleobase. Therefore, the effects of hydrogen bonding with the bases are approximately the same in all environments. Our results suggest that hydrogen bonding with the nucleobase may play an important role in the glycosidic bond cleavage in both pyrimidine and purine nucleotides in a variety of environments.

KsgA, a 16S rRNA adenine methyltransferase, has a novel DNA glycosylase/AP lyase activity to prevent mutations in Escherichia coli

The 5-formyluracil (5-foU), a major mutagenic oxidative damage of thymine, is removed from DNA by Nth, Nei and MutM in Escherichia coli. However, DNA polymerases can also replicate past the 5-foU by incorporating C and G opposite the lesion, although the mechanism of correction of the incorporated bases is still unknown. In this study, using a borohydride-trapping assay, we identified a protein trapped by a 5-foU/C-containing oligonucleotide in an extract from E. coli mutM nth nei mutant. The protein was subsequently purified from the E. coli mutM nth nei mutant and was identified as KsgA, a 16S rRNA adenine methyltransferase. Recombinant KsgA also formed the trapped complex with 5-foU/C- and thymine glycol (Tg)/C-containing oligonucleotides. Furthermore, KsgA excised C opposite 5-foU, Tg and 5-hydroxymethyluracil (5-hmU) from duplex oligonucleotides via a β-elimination reaction, whereas it could not remove the damaged base. In contrast, KsgA did not remove C opposite normal bases, 7,8-dihydro-8-oxoguanine and 2-hydroxyadenine. Finally, the introduction of the ksgA mutation increased spontaneous mutations in E. coli mutM mutY and nth nei mutants. These results demonstrate that KsgA has a novel DNA glycosylase/AP lyase activity for C mispaired with oxidized T that prevents the formation of mutations, which is in addition to its known rRNA adenine methyltransferase activity essential for ribosome biogenesis.

Angiotensin II induces DNA damage in the kidney

Increased activity of the renin angiotensin system with enhanced levels of angiotensin II leads to oxidative stress with endothelial dysfunction, hypertension, and atherosclerosis. Epidemiologic studies revealed a higher cancer mortality and an increased kidney cancer incidence in hypertensive patients. Because elevated angiotensin II levels might contribute to carcinogenesis, we tested whether angiotensin II induces DNA damage in the kidney. In isolated perfused mouse kidneys, as little as 1 nmol/L angiotensin II caused a significant increase in DNA strand breaks, measured with the comet assay. This damage was independent of the hemodynamic effect of angiotensin II and mediated by the angiotensin II type 1 receptor. Angiotensin II also caused double-strand breaks in the cells of the isolated perfused kidney, detected with an antibody against the double-strand break marker gamma-H2AX. Studies in cell culture allowed further characterization of the DNA damage induced by angiotensin II. Single- and double-strand breaks, abasic sites, and 7,8-dihydro-8-oxo-guanine, all types of oxidative DNA lesions, were detected in angiotensin II-treated renal cells. The majority of detected strand breaks was repaired within 1 hour, but double-strand breaks increased and persisted for at least 24 hours.

Escherichia coli HU protein has a role in the repair of abasic sites in DNA

HU is one of the most abundant DNA binding proteins in Escherichia coli. We find that it binds strongly to DNA containing an abasic (AP) site or tetrahydrofuran (THF) (apparent K(d) approximately 50 nM). It also possesses an AP lyase activity that cleaves at a deoxyribose but not at a THF residue. The binding and cleavage of an AP site was observed only with the HUalphabeta heterodimer. Site-specific mutations at K3 and R61 residues led to a change in substrate binding and cleavage. Both K3A(alpha)K3A(beta) and R61A(alpha)R61A(beta) mutant HU showed significant reduction in binding to DNA containing AP site; however, only R61A(alpha)R61A(beta) mutant protein exhibited significant loss in AP lyase activity. Both K3A(alpha)K3A(beta) and R61K(alpha)R61K(beta) showed slight reduction in AP lyase activities. The function of HU protein as an AP lyase was confirmed by the ability of hupA or hupB mutations to further reduce the viability of an E. coli dut(Ts) xth mutant, which generates lethal AP sites at 37 degrees C; the hupA and hupB derivatives, respectively, had a 6-fold and a 150-fold lower survival at 37 degrees C than did the parental strain. These data suggest, therefore, that HU protein plays a significant role in the repair of AP sites in E. coli.

A kinetic and thermodynamic study of the glycosidic bond cleavage in deoxyuridine

Density functional theory was used to study the thermodynamics and kinetics for the glycosidic bond cleavage in deoxyuridine. Two reaction pathways were characterized for the unimolecular decomposition in vacuo. However, these processes are associated with large reaction barriers and highly endothermic reaction energies, which is in agreement with experiments that suggest a (water) nucleophile is required for the nonenzymatic glycosidic bond cleavage. Two (S(N)1 and S(N)2) reaction pathways were characterized for direct hydrolysis of the glycosidic bond by a single water molecule; however, both pathways also involve very large barriers. Activation of the water nucleophile via partial proton abstraction steadily decreases the barrier and leads to a more exothermic reaction energy as the proton affinity of the molecule interacting with water increases. Indeed, our data suggests that the barrier heights and reaction energies range from that for hydrolysis by water to that for hydrolysis by the hydroxyl anion, which represents the extreme of (full) water activation (deprotonation). Hydrogen bonds between small molecules (hydrogen fluoride, water, or ammonia) and the nucleobase were found to further decrease the barrier and overall reaction energy but not to the extent that the same hydrogen-bonding interactions increase the acidity of the nucleobase. Our results suggest that the nature of the nucleophile plays a more important role in reducing the barrier to glycosidic bond cleavage than the nature of the small molecule bound, and models with more than one hydrogen fluoride molecule interacting with the nucleobase provide further support for this conclusion. Our results lead to a greater fundamental understanding of the effects of the nucleophile, activation of the nucleophile, and interactions with the nucleobase for this important biological reaction.

Environmental Effects on the Enhancement in Natural and Damaged DNA Nucleobase Acidity Because of Discrete Hydrogen-Bonding Interactions

The present study uses density functional theory to carefully consider the effects of the environment on the enhancement in (natural and damaged) DNA nucleobase acidities because of multiple hydrogen-bonding interactions. Although interactions with one small molecule can increase the acidity of the nucleobases by up to 60 kJ mol-1 in the gas phase, the maximum increase in enzymatic-like environments is expected to be approximately 40 kJ mol-1, which reduces to approximately 30 kJ mol-1 in water. Furthermore, the calculated (simultaneous) effects of two, three, or four molecules are increasingly less than the sum of the individual (additive) effects with an increase in the number and acidity of the small molecules bound or the dielectric constant of the solvent. Regardless of these trends, our calculations reveal that additional hydrogen-bonding interactions will have a significant effect on nucleobase acidity in a variety of environments, where the exact magnitude of the effect depends on the properties of the small molecule bound, the nucleobase binding site, and the solvent. The maximum increase in nucleobase acidity because of interactions with up to four small molecules is approximately 80 kJ mol-1 in enzymatic-like environments (or 65 kJ mol-1 in water). These results suggest that hydrogen-bonding interactions likely play an important role in many biological processes by changing the physical and chemical properties of the nucleobases.

Catalytic mechanism of Escherichia coli endonuclease VIII: roles of the intercalation loop and the zinc finger

Endonuclease VIII (Nei) excises oxidatively damaged pyrimidines from DNA and shares structural and functional homology with formamidopyrimidine-DNA glycosylase. Although the structure of Escherichia coli Nei is solved [Zharkov et al. (2002) EMBO J. 21, 789-800], the functions of many of its amino acid residues involved in catalysis and substrate specificity are not known. We constructed a series of Nei mutants that interfere with eversion of the damaged base from the helix (QLY69-71AAA, DeltaQLY69-71) or perturb the conserved zinc finger (R171A, Q261A). Steady-state kinetics were measured with these mutant enzymes using substrates containing 5,6-dihydrouracil, two enantiomers of thymine glycol, 8-oxo-7,8-dihydroguanine, and an abasic site positioned opposite each of the four canonical DNA bases. To some extent, all Nei mutants were deficient in processing damaged DNA, with mutations in the zinc finger generally having a more profound effect. Wild-type Nei showed prominent opposite-base specificity (G > C approximately = T > A) when the lesion was 5,6-dihydrouracil or cis-(5S,6R)-thymine glycol but not for other lesions tested. Mutations in the Q69-Y71 loop eliminated this effect. Only wild-type Nei and Nei-Q261A mutants could be reductively cross-linked to damaged base-containing DNA. Experiments involving trapping with NaBH4 and the kinetics of DNA cleavage catalyzed by Nei-Q261A suggested that this mutant was deficient in regenerating free enzyme from the Nei-DNA covalent complex formed during the reaction. We conclude that the opposite-base specificity of Nei is primarily governed by residues in the Q69-Y71 loop and that both this loop and the zinc finger contribute significantly to the substrate specificity of Nei.

Cloning and characterization of an ascidian homolog of the human 8-oxoguanine DNA glycosylase (Ogg1) that is involved in the repair of 8-oxo-7,8-dihydroguanine in DNA in Ciona intestinalis

PURPOSE

It is of interest to perform a systematic comparative analysis of the conserved domains in DNA glycosylases and the evolution of DNA base excision repair systems. Furthermore, it is important to characterize the roles and regulation of base excision repair during the development of organisms. To address these issues, we first identified 8-oxo-7,8-dihydroguanine (8-oxoG)-DNA glycosylase (Ogg1) of the ascidian Ciona intestinalis as a good model system.

MATERIALS AND METHODS

A cDNA clone coding for a peptide with homology to human Ogg1 was identified in the expressed sequence tag (EST) database from the Ciona cDNA resources. We examined whether CiOgg1 has DNA glycosylase/AP (apurinic/apyrimidinic) lyase activities for 8-oxoG-containing oligonucleotide. Furthermore, the expression level of CiOgg1 was compared in various tissues of Ciona intestinalis.

RESULTS

The CiOgg1gene encoded a protein of 351 amino acids, which shows 37% identity of amino acid sequence with human Ogg1. The Helix-hairpin-Helix motif was highly conserved. The ascidian enzyme had functional 8-oxoG-DNA glycosylase/AP lyase activities, which removed 8-oxoG opposite cytosine from DNA. Expression of the CiOgg1 significantly reduced the frequency of spontaneous G:C to T:A transversions in E. coli mutM mutY. The highest expression level was observed in testis in Ciona intestinalis.

CONCLUSIONS

The structure and functions of Ogg1 are well conserved in Ciona intestinalis. CiOgg1 is involved in the repair of 8-oxoG in DNA in Ciona intestinalis.

Mutagenic effects of abasic and oxidized abasic lesions in Saccharomyces cerevisiae

2-Deoxyribonolactone (L) and 2-deoxyribose (AP) are abasic sites that are produced by ionizing radiation, reactive oxygen species and a variety of DNA damaging agents. The biological processing of the AP site has been examined in the yeast Saccharomyces cerevisiae. However, nothing is known about how L is processed in this organism. We determined the bypass and mutagenic specificity of DNA containing an abasic site (AP and L) or the AP analog tetrahydrofuran (F) using an oligonucleotide transformation assay. The tetrahydrofuran analog and L were bypassed at 10-fold higher frequencies than the AP lesions. Bypass frequencies of lesions were greatly reduced in the absence of Rev1 or Polζ (rev3 mutant), but were only marginally reduced in the absence of Polη (rad30 mutant). Deoxycytidine was the preferred nucleotide inserted opposite an AP site whereas dA and dC were inserted at equal frequencies opposite F and L sites. In the rev1 and rev3 strains, dA was the predominant nucleotide inserted opposite these lesions. Overall, we conclude that both Rev1 and Polζ are required for the efficient bypass of abasic sites in yeast.

Effects of Hydrogen Bonding on the Acidity of Adenine, Guanine, and Their 8-Oxo Derivatives

Complexes between ammonia, water, or hydrogen fluoride and adenine, guanine, or their 8-oxo derivatives are investigated using density-functional theory. The binding strengths of the neutral and (N9) anionic complexes are considered for a variety of purine binding sites. The effects of hydrogen-bonding interactions on the (N9) acidity of the purine derivatives are considered as a function of the molecule bound and the binding site. It is found that hydrogen-bonding interactions with one molecule can increase the acidity of purine derivatives by up to 60 kJ mol(-1). The (calculated) simultaneous effects of up to four molecules on the acidity of the purine derivatives are also considered. Our data suggest that the effects of more than one molecule on the acidity of the purines are generally less than the sum of the individual (additive) effects, where the magnitude of the deviation from additivity increases with the number, as well as the acidity, of molecules bound. Nevertheless, the increase in the acidity due to additional hydrogen-bonding interactions is significant, where the effect of two, three, or four hydrogen-bonding interactions can be as large as approximately 95, 115, and 130 kJ mol(-1), respectively. The present study provides a greater fundamental understanding of hydrogen-bonding interactions involving the natural purines, as well as those generated through oxidative DNA damage, which may aid the understanding of important biological processes.

Two sequential phosphates 3' adjacent to the 8-oxoguanosine are crucial for lesion excision by E. coli Fpg protein and human 8-oxoguanine-DNA glycosylase

Escherichia coli formamidopyrimidine-DNA glycosylase (Fpg) and human 8-oxoguanine-DNA glycosylase (hOGG1) are base excision repair enzymes involved in the 8-oxoguanine (oxoG) repair pathway. Specific contacts between these enzymes and DNA phosphate groups play a significant role in DNA-protein interactions. To reveal the phosphates crucial for lesion excision by Fpg and hOGG1, modified DNA duplexes containing pyrophosphate and OEt-substituted pyrophosphate internucleotide (SPI) groups near the oxoG were tested as substrate analogues for both proteins. We have shown that Fpg and hOGG1 recognize and specifically bind the DNA duplexes tested. We have found that both enzymes were not able to excise the oxoG residue from DNA containing modified phosphates immediately 3' to the 8-oxoguanosine (oxodG) and one nucleotide 3' away from it. In contrast, they efficiently incised DNA duplexes bearing the same phosphate modifications 5' to the oxodG and two nucleotides 3' away from the lesion. The effect of these phosphate modifications on the substrate properties of oxoG-containing DNA duplexes is discussed. Non-cleavable oxoG-containing DNA duplexes bearing pyrophosphate or SPI groups immediately 3' to the oxodG or one nucleotide 3' away from it are specific inhibitors for both 8-oxoguanine-DNA glycosylases and can be used for structural studies of complexes comprising a wild-type enzymes bound to oxoG-containing DNA.

A comparison of two DNA base excision repair glycosylases from Arabidopsis thaliana

Plants contain the genes for both formamidopyrimidine-DNA glycosylase (FPG) and oxoguanine glycosylase (OGG). These enzymes play analogous roles in the base excision repair pathways of bacteria (FPG) and archaea, yeast, and mammals (OGG). Why have plants retained both genes? We tested one hypothesis by comparing the specificities of Arabidopsis FPG and OGG purified from Escherichia coli expression clones. Using depurinated DNA as substrate, the specific activity of Arabidopsis FPG was higher than that of Arabidopsis OGG. Using DNA oxidized by treatment with light in the presence of methylene blue, the specific activities of Arabidopsis FPG and OGG were equal. Using an oligonucleotide containing one oxoguanine (paired with C) and labeled with fluorescein, the specific activity of Arabidopsis OGG was greater than that of either FPG. The results support the hypothesis that genes for the two enzymes have been retained during evolution of plants for their specialized enzyme activities.

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.

Structural characterization of the Fpg family of DNA glycosylases

Until recently, the Fpg family was the only major group of DNA glycosylases for which no structural data existed. Prototypical members of this family, found in eukaryotes as well as prokaryotes, have now been crystallized as free proteins and as complexes with DNA. In this review, we analyze the available structural information for formamidopyrimidine-DNA glycosylase (Fpg) and endonuclease VIII (Nei). Special emphasis is placed on mechanisms by which these enzymes recognize and selectively excise cognate lesions from oxidatively damaged DNA. The problem of lesion recognition is considered in two parts: how the enzyme efficiently locates a single lesion embedded in a vast excess of DNA; and how the lesion is accommodated in a pocket near the active site of the enzyme. Although all crystal structures reported to date for the Fpg family lack the damaged base, functionally important residues that participate in DNA binding and enzyme catalysis have been clearly identified and other residues, responsible for substrate specificity, have been inferred.

Photochemical cross-linking of Escherichia coli Fpg protein to DNA duplexes containing phenyl(trifluoromethyl)diazirine groups

Formamidopyrimidine-DNA glycosylase (Fpg protein) of Escherichia coli is a DNA repair enzyme that excises oxidized purine bases, most notably the mutagenic 7-hydro-8-oxoguanine, from damaged DNA. In order to identify specific contacts between nucleobases of DNA and amino acids from the E. coli Fpg protein, photochemical cross-linking was employed using new reactive DNA duplexes containing 5-[4-[3-(trifluoromethyl)-3H-diazirin-3-yl]phenyl]-2'-deoxyuridine dU* residues near the 7-hydro-8-oxoguanosine (oxoG) lesion. The Fpg protein was found to bind specifically and tightly to the modified DNA duplexes and to incise them. The nicking efficiency of the DNA duplex containing a dU* residue 5' to the oxoG was higher as compared to oxidized native DNA. The conditions for the photochemical cross-linking of the reactive DNA duplexes and the Fpg protein have been optimized to yield as high as 10% of the cross-linked product. Our results suggest that the Fpg protein forms contacts with two nucleosides, one 5' adjacent to oxoG and the other 5' adjacent to the cytidine residue pairing with oxoG in the other strand. The approaches developed may be applicable to pro- and eukaryotic homologues of the E. coli Fpg protein as well as to other repair enzymes.

Use of crosslinking for revealing the DNA phosphate groups forming specific contacts with the E. coli Fpg protein

Specific contacts between DNA phosphate groups and positively charged nucleophilic amino acids from the Escherichia coli Fpg protein play a significant role in DNA-Fpg protein interaction. In order to identify these phosphate groups the chemical crosslinking procedure was carried out. The probing of the Fpg protein active center was performed using a series of reactive DNA duplexes containing both a single 7,8-dihydro-8-oxoguanosine (oxoG) residue and O-alkyl-substituted pyrophosphate internucleotide groups at the same time. Reactive internucleotide groups were introduced in dsDNA immediately 5' or 3' to the oxidative lesion and one or two nucleotides 5' or 3' away from it. We showed that the Fpg protein specifically binds to the modified DNA duplexes. The binding efficiency varied with the position of the reactive group and was higher for the duplexes containing substituted pyrophosphate groups at the ends of pentanucleotide with the oxoG in the center. The nicking efficiency of the DNA duplexes containing the reactive groups one or two nucleotides 5' away from the lesion was higher as compared to non-modified DNA duplex bearing only the oxidative damage. We found two novel non-hydrolizable substrate analogs for the Fpg protein containing pyrophosphate and substituted pyrophosphate groups 3' adjacent to the oxoG. Using crosslinking, we revealed the phosphate groups, 3' and 5' adjacent to the lesion, which have specific contacts with nucleophilic amino acids from the E. coli Fpg protein active center. The crosslinking efficiency achieved 30%. The approaches developed can be employed in the studies of pro- and eucaryotic homologs of the E. coli Fpg protein as well as other repair enzymes.

Ntg1 and Ntg2 proteins as 5-formyluracil-DNA glycosylases/AP lyases in Saccharomyces cerevisiae

PURPOSE

5-Formyluracil (5-foU) is a potentially mutagenic lesion of thymine produced in DNA by ionizing radiation and various chemical oxidants. The present authors reported previously that MutM, Nth and Nei in Escherichia coli removed 5-foU from DNA. The present study identified 5-foU DNA glycosylases in Saccharomyces cerevisiae in order to clarify the repair mechanisms of 5-foU in eukaryotic cells.

MATERIALS AND METHODS

The borohydride-trapping assay and DNA-nicking assay were carried out to detect and characterize the repair activities for 5-foU in extracts from S. cerevisiae with oligonucleotides containing 5-foU at specific sites.

RESULTS

Two proteins in crude extracts from S. cerevisiae formed covalent complexes with oligonucleotides containing site-specific 5-foU in the presence of NaBH4. Extracts from S. cerevisiae strains defective in either the NTG1 or the NTG2 gene lacked either one or the other of these two proteins. Purified Ntg1 and Ntg2 were trapped in such complexes by the 5-foU-containing oligonucleotides in the presence of NaBH4. Furthermore, purified Ntg1 and Ntg2 efficiently cleaved the oligonucleotide at the 5-foU site.

CONCLUSIONS

The results indicate that both Ntg1 and Ntg2 are involved in the repair of 5-foU in DNA, and thereby serve to reduce mutations in S. cerevisiae.

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.

Enzymology of the repair of free radicals-induced DNA damage

A number of intrinsic and extrinsic mutagens induce structural damage in cellular DNA. These DNA damages are cytotoxic, miscoding or both and are believed to be at the origin of cell lethality, tissue degeneration, ageing and cancer. In order to counteract immediately the deleterious effects of such lesions, leading to genomic instability, cells have evolved a number of DNA repair mechanisms including the direct reversal of the lesion, sanitation of the dNTPs pools, mismatch repair and several DNA excision pathways including the base excision repair (BER) nucleotide excision repair (NER) and the nucleotide incision repair (NIR). These repair pathways are universally present in living cells and extremely well conserved. This review is focused on the repair of lesions induced by free radicals and ionising radiation. The BER pathway removes most of these DNA lesions, although recently it was shown that other pathways would also be efficient in the removal of oxidised bases. In the BER pathway the process is initiated by a DNA glycosylase excising the modified and mismatched base by hydrolysis of the glycosidic bond between the base and the deoxyribose of the DNA, generating a free base and an abasic site (AP-site) which in turn is repaired since it is cytotoxic and mutagenic.

Identification of 5-formyluracil DNA glycosylase activity of human hNTH1 protein

5-formyluracil (5-foU) is a potentially mutagenic lesion of thymine produced in DNA by ionizing radiation and various chemical oxidants. The elucidation of repair mechanisms for 5-foU will yield important insights into the biological consequences of the lesion. Recently, we reported that 5-foU is recognized and removed from DNA by Escherichia coli enzymes Nth (endonuclease III), Nei (endonuclease VIII) and MutM (formamidopyrimidine DNA glycosylase). Human cells have been shown to have enzymatic activities that release 5-foU from X-ray-irradiated DNA, but the molecular identities of these activities are not yet known. In this study, we demonstrate that human hNTH1 (endonuclease III homolog) has a DNA glycosylase/AP lyase activity that recognizes 5-foU in DNA and removes it. hNTH1 cleaved 5-foU-containing duplex oligonucleotides via a beta-elimination reaction. It formed Schiff base intermediates with 5-foU-containing oligonucleotides. Furthermore, hNTH1 cleaved duplex oligonucleotides containing all of the 5-foU/N pairs (N = G, A, T or C). The specific activities of hNTH1 for cleavage of oligonucleotides containing 5-foU and thymine glycol were 0.011 and 0.045 nM/min/ng protein, respectively. These results indicate that hNTH1 has DNA glycosylase activity with the potential to recognize 5-foU in DNA and remove it in human cells.

Crystal structure of the Lactococcus lactis formamidopyrimidine-DNA glycosylase bound to an abasic site analogue-containing DNA

The formamidopyrimidine-DNA glycosylase (Fpg, MutM) is a bifunctional base excision repair enzyme (DNA glycosylase/AP lyase) that removes a wide range of oxidized purines, such as 8-oxoguanine and imidazole ring-opened purines, from oxidatively damaged DNA. The structure of a non-covalent complex between the Lactoccocus lactis Fpg and a 1,3-propanediol (Pr) abasic site analogue-containing DNA has been solved. Through an asymmetric interaction along the damaged strand and the intercalation of the triad (M75/R109/F111), Fpg pushes out the Pr site from the DNA double helix, recognizing the cytosine opposite the lesion and inducing a 60 degrees bend of the DNA. The specific recognition of this cytosine provides some structural basis for understanding the divergence between Fpg and its structural homologue endo nuclease VIII towards their substrate specificities. In addition, the modelling of the 8-oxoguanine residue allows us to define an enzyme pocket that may accommodate the extrahelical oxidized base.

Combining structural and bioinformatics methods for the analysis of functionally important residues in DNA glycosylases

An essential function of DNA glycosylases is the recognition and excision of damaged bases in DNA, thereby preserving genomic integrity. Lesion recognition is a multistep process, which is only partially revealed by structural analysis of the catalytically competent complex. The functional role of additional residues can be predicted by combining structural data with analysis of amino acid conservation. The following postulate underlies this approach: if a family or superfamily can be broken into subgroups with different substrate specificities, residues highly conserved between these subgroups represent those important for enzyme catalysis and structure maintenance while residues highly conserved within a subgroup but not between subgroups represent residues important for substrate specificity. We review the bioinformatics approach used for this quantitative analysis and describe its application to the Nth superfamily and Fpg family of DNA glycosylases. These results serve as a starting point in planning site-directed mutagenesis experiments to elucidate the functional role of similar and dissimilar residues in DNA repair and other proteins.

Structure of formamidopyrimidine-DNA glycosylase covalently complexed to DNA

Formamidopyrimidine-DNA glycosylase (Fpg) is a DNA repair enzyme that excises oxidized purines from damaged DNA. The Schiff base intermediate formed during this reaction between Escherichia coli Fpg and DNA was trapped by reduction with sodium borohydride, and the structure of the resulting covalently cross-linked complex was determined at a 2.1-A resolution. Fpg is a bilobal protein with a wide, positively charged DNA-binding groove. It possesses a conserved zinc finger and a helix-two turn-helix motif that participate in DNA binding. The absolutely conserved residues Lys-56, His-70, Asn-168, and Arg-258 form hydrogen bonds to the phosphodiester backbone of DNA, which is sharply kinked at the lesion site. Residues Met-73, Arg-109, and Phe-110 are inserted into the DNA helix, filling the void created by nucleotide eversion. A deep hydrophobic pocket in the active site is positioned to accommodate an everted base. Structural analysis of the Fpg-DNA complex reveals essential features of damage recognition and the catalytic mechanism of Fpg.

Structural analysis of an Escherichia coli endonuclease VIII covalent reaction intermediate

Endonuclease VIII (Nei) of Escherichia coli is a DNA repair enzyme that excises oxidized pyrimidines from DNA. Nei shares with formamidopyrimidine-DNA glycosylase (Fpg) sequence homology and a similar mechanism of action: the latter involves removal of the damaged base followed by two sequential beta-elimination steps. However, Nei differs significantly from Fpg in substrate specificity. We determined the structure of Nei covalently crosslinked to a 13mer oligodeoxynucleotide duplex at 1.25 A resolution. The crosslink is derived from a Schiff base intermediate that precedes beta-elimination and is stabilized by reduction with NaBH(4). Nei consists of two domains connected by a hinge region, creating a DNA binding cleft between domains. DNA in the complex is sharply kinked, the deoxyribitol moiety is bound covalently to Pro1 and everted from the duplex into the active site. Amino acids involved in substrate binding and catalysis are identified. Molecular modeling and analysis of amino acid conservation suggest a site for recognition of the damaged base. Based on structural features of the complex and site-directed mutagenesis studies, we propose a catalytic mechanism for Nei.

Mechanism of action of Escherichia coli formamidopyrimidine N-glycosylase: role of K155 in substrate binding and product release

Escherichia coli formamidopyrimidine N-glycosylase (fpg) is a DNA glycosylase with an associated beta,delta-lyase activity. We have recently shown that the highly conserved lysine residue K155 is important for base recognition. Incubation of a double-stranded DNA containing an abasic site with the wild-type fpg protein generated only beta,delta-product. However, incubation of a double-stranded DNA containing an abasic site opposite a small gap with fpg protein generated predominantly beta-product. These data suggested that the induction of a double-strand break by fpg led to the destabilization of the protein-DNA covalent intermediate, causing the fpg protein to prematurely dissociate from the DNA substrate. Furthermore, when a double-stranded DNA containing an abasic site opposite an A was used as a substrate, K155A mutant fpg protein yielded a mixture of beta- and beta,delta-products. These data suggested that K155 is essential for maintaining the stability of the intermediary protein-DNA covalent complex. Pre-steady-state burst kinetics showed that mutation in K155 led to the apparent disappearance of the initial burst, suggesting that the rate of product release from K155A is much greater than the rate of chemical reaction catalyzed by the mutant enzyme. This is consistent with the idea that K155A dissociates prematurely from the covalent complex, leading to a higher turnover number observed for K155A for DNA substrate containing an AP site.

Repair of oxidized purines and damaged pyrimidines by E. coli Fpg protein: different roles of proline 2 and lysine 57 residues

The Escherichia coli Fpg protein is involved in the repair of oxidized purines, including the highly mutagenic 7,8-dihydro-8-oxoguanine (8-oxoG). The Fpg protein also excises various oxidized pyrimidines with high efficiency. We examined, by targeted mutagenesis, the role of two highly conserved amino acid residues, proline 2 (P2) and lysine 57 (K57), on the catalytic activities of the Fpg protein toward a ring-fragmentation product of thymine (alpha RT) and 5,6-dihydrothymine (dHT). The following E. coli mutant Fpg proteins were investigated: lysine 57 --> glycine (FpgK57G), proline 2 --> glycine (FpgP2G), and proline 2 --> glutamic acid (FpgP2E). The FpgK57G protein had barely detectable alpha RT and dHT-DNA glycosylase activities and produced minute amounts of a Schiff-base complex upon reaction with alpha RT containing DNA. In contrast, the activity of an FpgP2G mutant toward alpha RT was comparable to the wild type activity and produced a Schiff-base complex with this substrate. FpgP2E was completely inactive in all the assays, in contrast, to the other mutants. The crystal structure of a homologous Fpg protein from an extreme thermophile, Thermus thermophilus HB8, reveals that it is composed of two distinct domains connected by a flexible hinge (Sugahara et al. [2000]: EMBO J 19:3857-3869). The N-terminal proline, one primary residue for enzymatic catalysis, is positioned at the bottom of a cleft in close proximity to lysine 52 (analogous to K57 of the E. coli Fpg). Based on the biochemical assays, together with the crystal structure of T. thermophilus HB8 Fpg protein, we propose a two-nucleophile model for the enzymatic catalysis.

Effect of single mutations on the specificity of Escherichia coli FPG protein for excision of purine lesions from DNA damaged by free radicals

The formamidopyrimidine N-DNA glycosylase (Fpg protein) of Escherichia coli is a DNA repair enzyme that is specific for the removal of purine-derived lesions from DNA damaged by free radicals and other oxidative processes. We investigated the effect of single mutations on the specificity of this enzyme for three purine-derived lesions in DNA damaged by free radicals. These damaging agents generate a multiplicity of base products in DNA, with the yields depending on the damaging agent. Wild type Fpg protein (wt-Fpg) removes 8-hydroxyguanine (8-OH-Gua), 4,6-diamino-5-formamidopyrimidine (FapyAde), and 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyGua) from damaged DNA with similar specificities. We generated five mutant forms of this enzyme with mutations involving Lys-57-->Gly (FpgK57G), Lys-57-->Arg (FpgK57R), Lys-155-->Ala (FpgK155A), Pro-2-->Gly (FpgP2G), and Pro-2-->Glu (FpgP2E), and purified them to homogeneity. FpgK57G and FpgK57R were functional for removal of FapyAde and FapyGua with a reduced activity when compared with wt-Fpg. The removal of 8-OH-Gua was different in that the specificity of FpgK57G was significantly lower for its removal from irradiated DNA, whereas wt-Fpg, FpgK57G, and FpgK57R excised 8-OH-Gua from H2O2/Fe(III)-EDTA/ascorbic acid-treated DNA with almost the same specificity. FpgK155A and FpgP2G had very low activity and FpgP2E exhibited no activity at all. Michaelis-Menten kinetics of excision was measured and kinetic constants were obtained. The results indicate an important role of Lys-57 residue in the activity of Fpg protein for 8-OH-Gua, but a lesser significant role for formamidopyrimidines. Mutations involving Lys-155 and Pro-2 had a dramatic effect with Pro-2-->Glu leading to complete loss of activity, indicating a significant role of these residues. The results show that point mutations significantly change the specificity of Fpg protein and suggest that point mutations are also expected to change specificities of other DNA repair enzymes.

Multiple forms of formamidopyrimidine-DNA glycosylase produced by alternative splicing in Arabidopsis thaliana

Formamidopyrimidine-DNA glycosylase (FPG) catalyzes the initial steps in the repair of DNA containing oxidized purines. Two cDNA clones from Arabidopsis thaliana encoding homologs of bacterial FPG have previously been described. We now report that there are at least five additional variants of FPG mRNA in Arabidopsis, each apparently produced from the same gene (AtMMH) by alternative splicing. Thus, AtMMH, like at least four other genes in the base excision repair pathway of human cells, produces multiple forms of protein product through alternative splicing. The variant forms of Arabidopsis FPG may be localized in different locations in the cells, may have different preferences for oxidized substrates, and/or may recruit different proteins that guide the subsequent steps of base excision repair.

Escherichia coli Nth and human hNTH1 DNA glycosylases are involved in removal of 8-oxoguanine from 8-oxoguanine/guanine mispairs in DNA

The spectrum of DNA damage caused by reactive oxygen species includes a wide variety of modifications of purine and pyrimidine bases. Among these modified bases, 7,8-dihydro-8-oxoguanine (8-oxoG) is an important mutagenic lesion. Base excision repair is a critical mechanism for preventing mutations by removing the oxidative lesion from the DNA. That the spontaneous mutation frequency of the Escherichia coli mutT mutant is much higher than that of the mutM or mutY mutant indicates a significant potential for mutation due to 8-oxoG incorporation opposite A and G during DNA replication. In fact, the removal of A and G in such a situation by MutY protein would fix rather than prevent mutation. This suggests the need for differential removal of 8-oxoG when incorporated into DNA, versus being generated in situ. In this study we demonstrate that E.coli Nth protein (endonuclease III) has an 8-oxoG DNA glycosylase/AP lyase activity which removes 8-oxoG preferentially from 8-oxoG/G mispairs. The MutM and Nei proteins are also capable of removing 8-oxoG from mispairs. The frequency of spontaneous G:C-->C:G transversions was significantly increased in E.coli CC103mutMnthnei mutants compared with wild-type, mutM, nth, nei, mutMnei, mutMnth and nthnei strains. From these results it is concluded that Nth protein, together with the MutM and Nei proteins, is involved in the repair of 8-oxoG when it is incorporated opposite G. Furthermore, we found that human hNTH1 protein, a homolog of E.coli Nth protein, has similar DNA glycosylase/AP lyase activity that removes 8-oxoG from 8-oxoG/G mispairs.

Role of the Escherichia coli and human DNA glycosylases that remove 5-formyluracil from DNA in the prevention of mutations

Ionizing radiation induces a wide variety of modifications to purine and pyrimidine residues. The exocyclic methyl group of thymine does not escape oxidative damage. Any 5-hydroperoxymethyluracil produced is spontaneously decomposed to form 5-formyluracil (5-foU) and 5-hydroxymethyluracil. The yield of 5-foU by ionizing radiation is roughly the same as that of 8-oxoguanine. 5-foU is a potential mutagenic damage in vitro and in vivo. Mammalian cells have an activity that removes 5-foU from X-irradiated DNA. Furthermore, the Nth, Nei and MutM proteins of E. coli have DNA glycosylase/AP lyase activities that recognize and remove 5-foU in DNA. The mutation frequency of 5-foU-containing plasmid increases when replicated in E. coli nthneimutMalkA. Single mutations in the nth, nei or mutM gene do not affect the mutation frequency. Therefore, these gene products are likely backup enzymes used to repair 5-foU in DNA. Furthermore, the human hNTH1 enzyme, a homologue of E. coli Nth, is found to have similar DNA glycosylase activity to that of the Nth protein.

Alternative forms of formamidopyrimidine-DNA glycosylase from Arabidopsis thaliana

Formamidopyrimidine-DNA glycosylase (FPG) catalyzes the initial steps in the repair of DNA containing oxidized purines. Two complementary DNA clones encoding homologs of bacterial FPG, designated Atfpg-1 and Atfpg-2, have been isolated from Arabidopsis thaliana. They are products of alternative splicing of the transcript of a single gene. Proteins encoded by both clones, AtFPG-1 and AtFPG-2, engineered to contain oligohistidine sequences on their C-terminal ends, were expressed in Escherichia coli and purified, and their activities were assayed. Both proteins cleaved DNA that contained apurinic sites, indicating that they have abasic lyase activity. AtFPG-1, but not AtFPG-2, showed significant cleavage of a double-stranded oligonucleotide that contained 8-oxo-guanine, indicating that the structural differences between the two proteins influence their enzymatic activities. However, both proteins were able to cleave the same sites in DNA that was treated with visible light in the presence of methylene blue.

Enzymatic processing of DNA containing tandem dihydrouracil by endonucleases III and VIII

Endonuclease III from Escherichia coli, yeast (yNtg1p and yNtg2p) and human and E.coli endonuclease VIII have a wide substrate specificity, and recognize oxidation products of both thymine and cytosine. DNA containing single dihydrouracil (DHU) and tandem DHU lesions were used as substrates for these repair enzymes. It was found that yNtg1p prefers DHU/G and exhibits much weaker enzymatic activity towards DNA containing a DHU/A pair. However, yNtg2p, E. coli and human endonuclease III and E.coli endonuclease VIII activities were much less sensitive to the base opposite the lesion. Although these enzymes efficiently recognize single DHU lesions, they have limited capacity for completely removing this damaged base when DHU is present on duplex DNA as a tandem pair. Both E.coli endonuclease III and yeast yNtg1p are able to remove only one DHU in DNA containing tandem lesions, leaving behind a single DHU at either the 3'- or 5'-terminus of the cleaved fragment. On the other hand, yeast yNtg2p can remove DHU remaining on the 5'-terminus of the 3' cleaved fragment, but is unable to remove DHU remaining on the 3'-terminus of the cleaved 5' fragment. In contrast, both human endonuclease III and E.coli endonuclease VIII can remove DHU remaining on the 3'-terminus of a cleaved 5' fragment, but are unable to remove DHU remaining on the 5'-terminus of a cleaved 3' fragment. Tandem lesions are known to be generated by ionizing radiation and agents that generate reactive oxygen species. The fact that these repair glycosylases have only a limited ability to remove the DHU remaining at the terminus suggests that participation of other repair enzymes is required for the complete removal of tandem lesions before repair synthesis can be efficiently performed by DNA polymerase.

Stimulation of human 8-oxoguanine-DNA glycosylase by AP-endonuclease: potential coordination of the initial steps in base excision repair

8-Oxoguanine-DNA glycosylase 1 (OGG1), with intrinsic AP lyase activity, is the major enzyme for repairing 7,8-dihydro-8-oxoguanine (8-oxoG), a critical mutagenic DNA lesion induced by reactive oxygen species. Human OGG1 excised the damaged base from an 8-oxoG. C-containing duplex oligo with a very low apparent k(cat) of 0.1 min(-1) at 37 degrees C and cleaved abasic (AP) sites at half the rate, thus leaving abasic sites as the major product. Excision of 8-oxoG by OGG1 alone did not follow Michaelis-Menten kinetics. However, in the presence of a comparable amount of human AP endonuclease (APE1) the specific activity of OGG1 was increased approximately 5-fold and Michaelis-Menten kinetics were observed. Inactive APE1, at a higher molar ratio, and a bacterial APE (Nfo) similarly enhanced OGG1 activity. The affinity of OGG1 for its product AP.C pair (K:(d) approximately 2.8 nM) was substantially higher than for its substrate 8-oxoG.C pair (K:(d) approximately 23. 4 nM) and the affinity for its final ss-elimination product was much lower (K:(d) approximately 233 nM). These data, as well as single burst kinetics studies, indicate that the enzyme remains tightly bound to its AP product following base excision and that APE1 prevents its reassociation with its product, thus enhancing OGG1 turnover. These results suggest coordinated functions of OGG1 and APE1, and possibly other enzymes, in the DNA base excision repair pathway.

Identification of repair enzymes for 5-formyluracil in DNA. Nth, Nei, and MutM proteins of Escherichia coli

5-Formyluracil (5-foU) is a potentially mutagenic lesion of thymine produced in DNA by ionizing radiation and various chemical oxidants. Although 5-foU has been reported to be removed from DNA by Escherichia coli AlkA protein in vitro, its repair mechanisms are not fully understood. In this study, we used the borohydride trapping assay to detect and characterize repair activities for 5-foU in E. coli extracts with site-specifically designed oligonucleotides containing a 5-foU at defined sites. The trapping assay revealed that there are three kinds of proteins that form covalent complexes with the 5-foU-containing oligonucleotides. Extracts from strains defective in the nth, nei, or mutM gene lacked one of the proteins. All of the trapped complexes were completely lost in extracts from the nth nei mutM triple mutant. The introduction of a plasmid carrying the nth, nei, or mutM gene into the E. coli triple mutant restored the formation of the corresponding protein-DNA complex. Purified Nth, Nei, and MutM proteins were trapped by the 5-foU-containing oligonucleotide to form the complex in the presence of NaBH(4). Furthermore, the purified Nth, Nei, and MutM proteins efficiently cleaved the oligonucleotide at the 5-foU site. In addition, 5-foU was site-specifically incorporated into plasmid pSVK3, and the resulting plasmid was replicated in E. coli. The mutation frequency of the plasmid was significantly increased in the E. coli nth nei mutM alkA mutant, compared with the wild-type and alkA strains. From these results it is concluded that the Nth, Nei, and MutM proteins are involved in the repair pathways for 5-foU that serve to avoid mutations in E. coli.

A deoxyinosine specific endonuclease from hyperthermophile, Archaeoglobus fulgidus: a homolog of Escherichia coli endonuclease V

Deoxyadenosine undergoes spontaneous deamination to deoxyinosine in DNA. Based on amino acids sequence homology, putative homologs of endonuclease V were identified in several organisms including archaebacteria, eubacteria as well as eukaryotes. The translated amino acid sequence of the Archaeoglobus fulgidus nfi gene shows 39% identity and 55% similarity to the E. coli nfi gene. A. fulgidus endonuclease V was cloned and expressed in E. coli as a C-terminal hexa-histidine fusion protein. The C-terminal fusion protein was purified to apparent homogeneity by a combination of Ni(++) affinity and MonoS cation exchange liquid chromatography. The purified C-terminal fusion protein has a molecular weight of about 25kDa and showed endonuclease activity towards DNA containing deoxyinosine. A. fulgidus endonuclease V has an absolute requirement for Mg(2+) and an optimum reaction temperature at 85 degrees C. However, in contrast to E. coli endonuclease V, which has a wide substrate spectrum, endonuclease V from A. fulgidus recognized only deoxyinosine. These data suggest that the deoxyinosine cleavage activity is a primordial activity of endonuclease V and that multiple enzymatic activities of E. coli endonuclease V were acquired later during evolution.

Identification, characterization, and purification of DNA glycosylase/AP lyases by reductive crosslinking to 2'-deoxyribooligonucleotides containing specific base lesions

This paper describes a reductive amination crosslinking protocol that facilitates identification and characterization of a class of DNA repair enzymes, DNA glycosylase/AP lyases, which are involved in base excision repair. This crosslinking technique has been used to identify enzymes in crude extracts and in partially purified enzyme preparations, to isolate proteins for sequencing, and to confirm the reaction mechanism of members of this enzyme family. Chemical reduction of the Schiff's base enzyme-substrate intermediate to a stable amine results in the formation of an irreversible covalent bond between the substrate lesion situated within a 2'-deoxyoligonucleotide and the repair enzyme. This complex can be detected by gel electrophoresis and can also be isolated and analyzed by amino acid sequencing.

Substrate specificity and reaction mechanism of murine 8-oxoguanine-DNA glycosylase

Genomic DNA is prone to oxidation by reactive oxygen species. A major product of DNA oxidation is the miscoding base 8-oxoguanine (8-oxoG). The mutagenic effects of 8-oxoG in mammalian cells are prevented by a DNA repair system consisting of 8-oxoguanine-DNA glycosylase (Ogg1), adenine-DNA glycosylase, and 8-oxo-dGTPase. We have cloned, overexpressed, and characterized mOgg1, the product of the murine ogg1 gene. mOgg1 is a DNA glycosylase/AP lyase belonging to the endonuclease III family of DNA repair enzymes. The AP lyase activity of mOgg1 is significantly lower than its glycosylase activity. mOgg1 releases 8-oxoG from DNA when paired with C, T, or G, but efficient DNA strand nicking is observed only with 8-oxoG:C. Binding of mOgg1 to oligonucleotides containing 8-oxoG:C is strong (K(D) = 51.5 nm), unlike other mispairs. The average residence time for mOgg1 bound to substrate containing 8-oxoG:C is 18.3 min; the time course for accumulation of the NaBH(4)-sensitive intermediate suggests a two-step reaction mechanism. Various analogs of 8-oxoG were tested as substrates for mOgg1. An electron-withdrawing or hydrogen bond acceptor moiety at C8 is required for efficient binding of mOgg1. A substituent at C6 and a keto group at C8 are required for cleavage. The proposed mechanism of 8-oxoG excision involves protonation of O(8) or the deoxyribose oxygen moiety.

Crystal structure of a repair enzyme of oxidatively damaged DNA, MutM (Fpg), from an extreme thermophile, Thermus thermophilus HB8

The MutM [formamidopyrimidine DNA glycosylase (Fpg)] protein is a trifunctional DNA base excision repair enzyme that removes a wide range of oxidatively damaged bases (N-glycosylase activity) and cleaves both the 3'- and 5'-phosphodiester bonds of the resulting apurinic/apyrimidinic site (AP lyase activity). The crystal structure of MutM from an extreme thermophile, Thermus thermophilus HB8, was determined at 1.9 A resolution with multiwavelength anomalous diffraction phasing using the intrinsic Zn(2+) ion of the zinc finger. MutM is composed of two distinct and novel domains connected by a flexible hinge. There is a large, electrostatically positive cleft lined by highly conserved residues between the domains. On the basis of the three-dimensional structure and taking account of previous biochemical experiments, we propose a DNA-binding mode and reaction mechanism for MutM. The locations of the putative catalytic residues and the two DNA-binding motifs (the zinc finger and the helix-two-turns-helix motifs) suggest that the oxidized base is flipped out from double-stranded DNA in the binding mode and excised by a catalytic mechanism similar to that of bifunctional base excision repair enzymes.

Role of the N-terminal proline residue in the catalytic activities of the Escherichia coli Fpg protein

The Escherichia coli Fpg protein is a DNA glycosylase/AP lyase. It removes, in DNA, oxidized purine residues, including the highly mutagenic C8-oxo-guanine (8-oxoG). The catalytic mechanism is believed to involve the formation of a transient Schiff base intermediate formed between DNA containing an oxidized residue and the N-terminal proline of the Fpg protein. The importance and the role of this proline upon the various catalytic activities of the Fpg protein was examined by targeted mutagenesis, resulting in the construction of three mutant Fpg proteins: Pro-2 --> Gly (FpgP2G), Pro-2 --> Thr (FpgP2T), and Pro-2 --> Glu (FpgP2E). The formamidopyrimidine DNA glycosylase activities of FpgP2G and FpgP2T were comparable and accounted for 10% of the wild-type activity. FpgP2G and FpgP2T had barely detectable 8-oxoG-DNA glycosylase activity and produced minute Schiff base complex with 8-oxoG/C DNA. FpgP2G and FpgP2T mutants did not cleave a DNA containing preformed AP site but readily produced Schiff base complex with this substrate. FpgP2E was completely inactive in all the assays. The binding constants of the different mutants when challenged with a duplex DNA containing a tetrahydrofuran residue were comparable. The mutant Fpg proteins barely or did not complement in vivo the spontaneous transitions G/C --> T/A in E. coli BH990 (fpg mutY) cells. These results show the mandatory role of N-terminal proline in the 8-oxoG-DNA glycosylase activity of the Fpg protein in vitro and in vivo as well as in its AP lyase activity upon preformed AP site but less in the 2,6-diamino-4-hydroxy-5-N-methylformamidopyrimidine-DNA glycosylase activity.