Correlation between sequence-dependent glycosylase repair and the thermal stability of oligonucleotide duplexes containing 1, N6-ethenoadenine

In What Ways Do Synthetic Nucleotides and Natural Base Lesions Alter the Structural Stability of G-Quadruplex Nucleic Acids?

Synthetic analogs of natural nucleotides have long been utilized for structural studies of canonical and noncanonical nucleic acids, including the extensively investigated polymorphic G-quadruplexes (GQs). Dependence on the sequence and nucleotide modifications of the folding landscape of GQs has been reviewed by several recent studies. Here, an overview is compiled on the thermodynamic stability of the modified GQ folds and on how the stereochemical preferences of more than 70 synthetic and natural derivatives of nucleotides substituting for natural ones determine the stability as well as the conformation. Groups of nucleotide analogs only stabilize or only destabilize the GQ, while the majority of analogs alter the GQ stability in both ways. This depends on the preferred syn or anti N-glycosidic linkage of the modified building blocks, the position of substitution, and the folding architecture of the native GQ. Natural base lesions and epigenetic modifications of GQs explored so far also stabilize or destabilize the GQ assemblies. Learning the effect of synthetic nucleotide analogs on the stability of GQs can assist in engineering a required stable GQ topology, and exploring the in vitro action of the single and clustered natural base damage on GQ architectures may provide indications for the cellular events.

Mutation Spectrum Induced by 8-Bromoguanine, a Base Damaged by Reactive Brominating Species, in Human Cells

To date, the types of mutations caused by 8-bromoguanine (8BrG), a major base lesion induced by reactive brominating species during inflammation, in human cells and the 8BrG repair system remain largely unknown. In this study, we performed a supF forward mutation assay using a shuttle vector plasmid containing a single 8BrG in three kinds of human cell lines and revealed that 8BrG in DNA predominantly induces a G → T mutation but can also induce G → C, G → A, and delG mutations in human cells. Next, we tested whether eight kinds of DNA glycosylases (MUTYH, MPG, NEIL1, OGG1, SMUG1, TDG, UNG2, and NTHL1) are capable of repairing 8BrG mispairs with any of the four bases using a DNA cleavage activity assay. We found that both the SMUG1 protein and the TDG protein exhibit DNA glycosylase activity against thymine mispaired with 8BrG and that the MUTYH protein exhibits DNA glycosylase activity against adenine mispaired with 8BrG. These results suggest that 8BrG induces some types of mutations, chiefly a G → T mutation, in human cells, and some DNA glycosylases are involved in the repair of 8BrG.

Slow repair of lipid peroxidation-induced DNA damage at p53 mutation hotspots in human cells caused by low turnover of a DNA glycosylase

Repair of oxidative stress- and inflammation-induced DNA lesions by the base excision repair (BER) pathway prevents mutation, a form of genomic instability which is often observed in cancer as 'mutation hotspots'. This suggests that some sequences have inherent mutability, possibly due to sequence-related differences in repair. This study has explored intrinsic mutability as a consequence of sequence-specific repair of lipid peroxidation-induced DNA adduct, 1, N(6)-ethenoadenine (εA). For the first time, we observed significant delay in repair of ϵA at mutation hotspots in the tumor suppressor gene p53 compared to non-hotspots in live human hepatocytes and endothelial cells using an in-cell real time PCR-based method. In-cell and in vitro mechanism studies revealed that this delay in repair was due to inefficient turnover of N-methylpurine-DNA glycosylase (MPG), which initiates BER of εA. We determined that the product dissociation rate of MPG at the hotspot codons was ≈5-12-fold lower than the non-hotspots, suggesting a previously unknown mechanism for slower repair at mutation hotspots and implicating sequence-related variability of DNA repair efficiency to be responsible for mutation hotspot signatures.

APE1 incision activity at abasic sites in tandem repeat sequences

Repetitive DNA sequences, such as those present in microsatellites and minisatellites, telomeres, and trinucleotide repeats (linked to fragile X syndrome, Huntington disease, etc.), account for nearly 30% of the human genome. These domains exhibit enhanced susceptibility to oxidative attack to yield base modifications, strand breaks, and abasic sites; have a propensity to adopt non-canonical DNA forms modulated by the positions of the lesions; and, when not properly processed, can contribute to genome instability that underlies aging and disease development. Knowledge on the repair efficiencies of DNA damage within such repetitive sequences is therefore crucial for understanding the impact of such domains on genomic integrity. In the present study, using strategically designed oligonucleotide substrates, we determined the ability of human apurinic/apyrimidinic endonuclease 1 (APE1) to cleave at apurinic/apyrimidinic (AP) sites in a collection of tandem DNA repeat landscapes involving telomeric and CAG/CTG repeat sequences. Our studies reveal the differential influence of domain sequence, conformation, and AP site location/relative positioning on the efficiency of APE1 binding and strand incision. Intriguingly, our data demonstrate that APE1 endonuclease efficiency correlates with the thermodynamic stability of the DNA substrate. We discuss how these results have both predictive and mechanistic consequences for understanding the success and failure of repair protein activity associated with such oxidatively sensitive, conformationally plastic/dynamic repetitive DNA domains.

Formation and repair of tobacco carcinogen-derived bulky DNA adducts

DNA adducts play a central role in chemical carcinogenesis. The analysis of formation and repair of smoking-related DNA adducts remains particularly challenging as both smokers and nonsmokers exposed to smoke are repetitively under attack from complex mixtures of carcinogens such as polycyclic aromatic hydrocarbons and N-nitrosamines. The bulky DNA adducts, which usually have complex structure, are particularly important because of their biological relevance. Several known cellular DNA repair pathways have been known to operate in human cells on specific types of bulky DNA adducts, for example, nucleotide excision repair, base excision repair, and direct reversal involving O⁶-alkylguanine DNA alkyltransferase or AlkB homologs. Understanding the mechanisms of adduct formation and repair processes is critical for the assessment of cancer risk resulting from exposure to cigarette smoke, and ultimately for developing strategies of cancer prevention. This paper highlights the recent progress made in the areas concerning formation and repair of bulky DNA adducts in the context of tobacco carcinogen-associated genotoxic and carcinogenic effects.

Energetic signatures of single base bulges: thermodynamic consequences and biological implications

DNA bulges are biologically consequential defects that can arise from template-primer misalignments during replication and pose challenges to the cellular DNA repair machinery. Calorimetric and spectroscopic characterizations of defect-containing duplexes reveal systematic patterns of sequence-context dependent bulge-induced destabilizations. These distinguishing energetic signatures are manifest in three coupled characteristics, namely: the magnitude of the bulge-induced duplex destabilization (DeltaDeltaG(Bulge)); the thermodynamic origins of DeltaDeltaG(Bulge) (i.e. enthalpic versus entropic); and, the cooperativity of the duplex melting transition (i.e. two-state versus non-two state). We find moderately destabilized duplexes undergo two-state dissociation and exhibit DeltaDeltaG(Bulge) values consistent with localized, nearest neighbor perturbations arising from unfavorable entropic contributions. Conversely, strongly destabilized duplexes melt in a non-two-state manner and exhibit DeltaDeltaG(Bulge) values consistent with perturbations exceeding nearest-neighbor expectations that are enthalpic in origin. Significantly, our data reveal an intriguing correlation in which the energetic impact of a single bulge base centered in one strand portends the impact of the corresponding complementary bulge base embedded in the opposite strand. We discuss potential correlations between these bulge-specific differential energetic profiles and their overall biological implications in terms of DNA recognition, repair and replication.

Kinetic mechanism for the flipping and excision of 1,N(6)-ethenoadenine by human alkyladenine DNA glycosylase

Human alkyladenine DNA glycosylase initiates the repair of a wide variety of alkylated and deaminated purine lesions in DNA. In this study, we take advantage of the natural fluorescence of the 1,N(6)-ethenoadenosine (epsilonA) lesion and report a kinetic analysis of binding, nucleotide flipping, base excision, and product release. The transient changes in the fluorescence of epsilonA revealed the existence of two distinct complexes that are formed prior to the hydrolysis step. An initial recognition complex forms rapidly and is characterized by partial disruption of the stacking interactions of the lesioned base. Subsequently, a very stable extrahelical complex is formed in which the epsilonA lesion is strongly quenched by interactions in the AAG active site pocket. Our results indicate that DNA binding and base flipping take place on the millisecond to second time scale. N-Glycosidic bond cleavage is much slower, taking place on the minute time scale. A pulse-chase experiment was used to demonstrate that even for the tightly bound epsilonA substrate, the extrahelical complex is not fully committed to excision. Nevertheless, flipping of epsilonA is highly favorable, and we calculate that the equilibrium constant for flipping is approximately 1300. This kinetic mechanism has important biological implications. First, two-step binding provides multiple opportunities to discriminate between damaged and undamaged nucleotides. Second, a rapid equilibrium flipping mechanism maximizes specificity for damaged versus undamaged bases, since undamaged bases generally form stronger base pairs than damaged bases. Finally, the highly favorable equilibrium for flipping of epsilonA ensures that epsilonA removal is independent of sequence context and highly efficient despite the relatively slow rate of N-glycosidic bond hydrolysis.

Substrate specificity and sequence-dependent activity of the Saccharomyces cerevisiae 3-methyladenine DNA glycosylase (Mag)

DNA glycosylases initiate base excision repair by first binding, then excising aberrant DNA bases. Saccharomyces cerevisiae encodes a 3-methyladenine (3MeA) DNA glycosylase, Mag, that recognizes 3MeA and various other DNA lesions including 1,N6-ethenoadenine (epsilon A), hypoxanthine (Hx) and abasic (AP) sites. In the present study, we explore the relative substrate specificity of Mag for these lesions and in addition, show that Mag also recognizes cisplatin cross-linked adducts, but does not catalyze their excision. Through competition binding and activity studies, we show that in the context of a random DNA sequence Mag binds epsilon A and AP-sites the most tightly, followed by the cross-linked 1,2-d(ApG) cisplatin adduct. While epsilon A binding and excision by Mag was robust in this sequence context, binding and excision of Hx was extremely poor. We further studied the recognition of epsilon A and Hx by Mag, when these lesions are present at different positions within A:T and G:C tracts. Overall, epsilon A was slightly less well excised from each position within the A:T and G:C tracts compared to excision from the random sequence, whereas Hx excision was greatly increased in these sequence contexts (by up to 7-fold) compared to the random sequence. However, given most sequence contexts, Mag had a clear preference for epsilon A relative to Hx, except in the TTXTT (X=epsilon A or Hx) sequence context from which Mag removed both lesions with almost equal efficiency. We discuss how DNA sequence context affects base excision by various 3MeA DNA glycosylases.

Sequence effects of aminofluorene-modified DNA duplexes: thermodynamic and circular dichroism properties

Circular dichroism (CD) and UV-melting experiments were conducted with 16 oligodeoxynucleotides modified by the carcinogen 2-aminofluorene, whose sequence around the lesion was varied systematically [d(CTTCTNG[AF]NCCTC), N = G, A, C, T], to gain insight into the factors that determine the equilibrium between base-displaced stacked (S) and external B-type (B) duplex conformers. Differing stabilities among the duplexes can be attributed to different populations of S and B conformers. The AF modification always resulted in sequence-dependent thermal (T(m)) and thermodynamic (-DeltaG degrees ) destabilization. The population of B-type conformers derived from eight selected duplexes (i.e. -AG*N- and -CG*N-) was inversely proportional to the -DeltaG degrees and T(m) values, which highlights the importance of carcinogen/base stacking in duplex stabilization even in the face of disrupted Watson-Crick base pairing in S-conformation. CD studies showed that the extent of the adduct-induced negative ellipticities in the 290-350 nm range is correlated linearly with -DeltaG degrees and T(m), but inversely with the population of B-type conformations. Taken together, these results revealed a unique interplay between the extent of carcinogenic interaction with neighboring base pairs and the thermodynamic properties of the AF-modified duplexes. The sequence-dependent S/B heterogeneities have important implications in understanding how arylamine-DNA adducts are recognized in nucleotide excision repair.

Alkylpurine-DNA-N-glycosylase excision of 7-(hydroxymethyl)-1,N6-ethenoadenine, a glycidaldehyde-derived DNA adduct

Glycidaldehyde (GDA) is a bifunctional alkylating agent that has been shown to be mutagenic in vitro and carcinogenic in rodents. However, the molecular mechanism by which it exerts these effects is not established. GDA is capable of forming exocyclic hydroxymethyl-substituted etheno adducts on base residues in vitro. One of them, 7-(hydroxymethyl)-1,N6-ethenoadenine (7-hm-epsilonA), was identified as the principal adduct in mouse skin treated with GDA or a glycidyl ether. In this work, using defined oligonucleotides containing a site-specific 7-hm-epsilonA, the human and mouse alkylpurine-DNA-N-glycosylases (APNGs), responsible for the removal of the analogous 1,N6-ethenoadenine (epsilonA) adduct, are shown to recognize and excise 7-hm-epsilonA. Such an activity can be significantly modulated by both 5' neighboring and opposite sequence contexts. The efficiency of human or mouse APNG for excision of 7-hm-epsilonA is about half that, or similar to the excision of epsilonA, respectively. When human or mouse cell-free extracts were tested, however, the extent of 7-hm-epsilonA excision is dramatically lower than that for epsilonA, suggesting that, in the crude extracts, the APNG activities toward these two adducts are differentially affected. Using cell-free extracts from APNG deficient mice, this enzyme is shown to be the primary glycosylase excising 7-hm-epsilonA. A structural approach, using molecular modeling, was employed to examine how the structure of the 7-hm-epsilonA adduct affects DNA conformation, as compared to the epsilonA adduct. These novel substrate specificities could have both biological and structural implications.

Human 3-methyladenine-DNA glycosylase: effect of sequence context on excision, association with PCNA, and stimulation by AP endonuclease

Human 3-methyladenine-DNA glycosylase (MPG protein) is involved in the base excision repair (BER) pathway responsible mainly for the repair of small DNA base modifications. It initiates BER by recognizing DNA adducts and cleaving the glycosylic bond leaving an abasic site. Here, we explore several of the factors that could influence excision of adducts recognized by MPG, including sequence context, effect of APE1, and interaction with other proteins. To investigate sequence context, we used 13 different 25 bp oligodeoxyribonucleotides containing a unique hypoxanthine residue (Hx) and show that the steady-state specificity of Hx excision by MPG varied by 17-fold. If APE1 protein is used in the reaction for Hx removal by MPG, the steady-state kinetic parameters increase by between fivefold and 27-fold, depending on the oligodeoxyribonucleotide. Since MPG has a role in removing adducts such as 3-methyladenine that block DNA synthesis and there is a potential sequence for proliferating cell nuclear antigen (PCNA) interaction, we hypothesized that MPG protein could interact with PCNA, a protein involved in repair and replication. We demonstrate that PCNA associates with MPG using immunoprecipitation with either purified proteins or whole cell extracts. Moreover, PCNA binds to both APE1 and MPG at different sites, and loading PCNA onto a nicked, closed circular substrate with a unique Hx residue enhances MPG catalyzed excision. These data are consistent with an interaction that facilitates repair by MPG or APE1 by association with PCNA. Thus, PCNA could have a role in short-patch BER as well as in long-patch BER. Overall, the data reported here show how multiple factors contribute to the activity of MPG in cells.

Repair of exocyclic DNA adducts: rings of complexity

Exocyclic DNA adducts are mutagenic lesions that can be formed by both exogenous and endogenous mutagens/carcinogens. These adducts are structurally analogs but can differ in certain features such as ring size, conjugation, planarity and substitution. Although the information on the biological role of the repair activities for these adducts is largely unknown, considerable progress has been made on their reaction mechanisms, substrate specificities and kinetic properties that are affected by adduct structures. At least four different mechanisms appear to have evolved for the removal of specific exocyclic adducts. These include base excision repair, nucleotide excision repair, mismatch repair, and AP endonuclease-mediated repair. This overview highlights the recent progress in such areas with emphasis on structure-activity relationships. It is also apparent that more information is needed for a better understanding of the biological and structural implications of exocyclic adducts and their repair.

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.

Influence of local duplex stability and N6-methyladenine on uracil recognition by mismatch-specific uracil-DNA glycosylase (Mug)

To maintain genomic integrity, DNA repair enzymes continually remove damaged bases and lesions resulting from endogenous and exogenous processes. These repair enzymes must distinguish damaged bases from normal bases to prevent the inadvertent removal of normal bases, which would promote genomic instability. The mechanisms by which this high level of specificity is accomplished are as yet unresolved. One member of the uracil-DNA glycosylase family of repair enzymes, Escherichia coli mismatch-specific uracil-DNA glycosylase (Mug), is reported to distinguish U:G mispairs from U:A base pairs based upon specific contacts with the mispaired guanine after flipping the target uracil out of the duplex. However, recent studies suggest other mechanisms for base selection, including local duplex stability. In this study, we used the modified base N6-methyladenine to probe the effect of local helix perturbation on Mug recognition of uracil. N6-Methyladenine is found in E. coli as part of both the mismatch repair and restriction-modification systems. In its cis isomer, N6-methyladenine destabilizes hydrogen bonding by interfering with pseudo-Watson-Crick base pairing. It is observed that the selection of uracil by Mug is sequence dependent and that uracil residues in sequences of reduced thermostability are preferentially removed. The replacement of adenine by N6-methyladenine increases the frequency of removal of the uracil residue paired opposite the modified adenine. These results are in accord with suggestions that local helix stability is an important determinant of base recognition by some DNA repair enzymes and provide a potential strategy for identifying the sequence location of modified bases in DNA.

Active-site clashes prevent the human 3-methyladenine DNA glycosylase from improperly removing bases

The human 3-methyladenine DNA glycosylase (AAG, MPG) removes a diverse array of damaged purines via a nucleotide-flipping mechanism. In the crystal structure of AAG bound to DNA containing 1,N(6) ethenoadenine, an asparagine (N169) occupies the active-site floor, in close proximity to the C-2 position of the flipped-out 1,N(6) ethenoadenine. We engineered site-specific AAG mutants to determine whether N169 prevents normal bases from mistakenly entering the active site. Substituting alanine or serine resulted in mutants that excised substrates at a faster rate than wild-type. Furthermore, these mutants acquired the ability to excise normal guanine within mispairs but not opposite cytosine. The results suggest that AAG can recognize helical deformations, such as mispairs. However, the active site then prevents the mistaken excision of bases, which prevents AAG from acquiring a mutator activity.

Structural insights by molecular dynamics simulations into differential repair efficiency for ethano-A versus etheno-A adducts by the human alkylpurine-DNA N-glycosylase

1,N6-ethenoadenine adducts (epsilonA) are formed by known environmental carcinogens and found to be removed by human alkylpurine-DNA N-glycosylase (APNG). 1,N6-ethanoadenine (EA) adducts differ from epsilonA by change of a double bond to a single bond in the 5-member exocyclic ring and are formed by chloroethyl nitrosoureas, which are used in cancer therapy. In this work, using purified recombinant human APNG, we show that EA is a substrate for the enzyme. However, the excision efficiency of EA was 65-fold lower than that of epsilonA. Molecular dynamics simulation produced similar structural motifs for epsilonA and EA when incorporated into a DNA duplex, suggesting that there are no specific conformational features in the DNA duplex which can account for the differences in repair efficiency. However, when EA was modeled into the APNG active site, based on the APNG/epsilonA-DNA crystallographic coordinates, in structures produced by 2 ns molecular dynamics simulation, we observed weakening in the stacking interaction between EA and aromatic side chains of the key amino acids in the active site. In contrast, the planar epsilonA is better stacked at the enzyme active site. We propose that the observed destabilization of the EA adduct at the active site, such as reduced stacking interactions, could account for the biochemically observed weaker recognition of EA by APNG as compared to epsilonA.

Binding of specific DNA base-pair mismatches by N-methylpurine-DNA glycosylase and its implication in initial damage recognition

Most DNA glycosylases including N-methylpurine-DNA glycosylase (MPG), which initiate DNA base excision repair, have a wide substrate range of damaged or altered bases in duplex DNA. In contrast, uracil-DNA glycosylase (UDG) is specific for uracil and excises it from both single-stranded and duplex DNAs. Here we show by DNA footprinting analysis that MPG, but not UDG, bound to base-pair mismatches especially to less stable pyrimidine-pyrimidine pairs, without catalyzing detectable base cleavage. Thermal denaturation studies of these normal and damaged (e.g. 1,N(6)-ethenoadenine, varepsilonA) base mispairs indicate that duplex instability rather than exact fit of the flipped out damaged base in the catalytic pocket is a major determinant in the initial recognition of damage by MPG. Finally, based on our determination of binding affinity and catalytic efficiency we conclude that the initial recognition of substrate base lesions by MPG is dependent on the ease of flipping of the base from unstable pairs to a flexible catalytic pocket.

DNA substrates containing defined oxidative base lesions and their application to study substrate specificities of base excision repair enzymes

Reactive oxygen species generate structurally diverse base lesions in DNA. These lesions are primarily removed by base excision repair (BER) enzymes in prokaryotic and eukaryotic cells. Biochemical properties of BER enzymes such as substrate specificity, enzymatic parameters, and action mechanisms can be best studied by employing defined oligonucleotide and DNA substrates. Currently available methods are listed to prepare defined DNA substrates containing oxidative base damage and analogs. BER enzymes for oxidative base damage are classified into two subgroups that recognize pyrimidine lesions (Endo III homologs) and purine lesions (Fpg homologs), though E. coli Fpg exhibits weak repair activity for certain pyrimidine damage. Recently, several interesting findings have been reported in relation to the substrate specificity of BER enzymes. Saccharomyces cerevisiae Endo III homologs (NTG1 and NTG2) have been shown to recognize formamidopyrimidine (Fapy) lesions that are derived from purine. Endo III and Endo VIII have a very weak activity to dihydrothymine in comparison with thymine glycol. Excision of 7,8-dihydro-8-oxoguanine by Fpg and human OGG1 is paired-base-dependent, whereas that of Fapy is essentially paired-base-independent. The repair efficiency of BER enzymes is affected by surrounding sequence contexts. In general, the sequence context effect appears to be more pronounced for Fpg homologs than Endo III homologs.

Effect of sequence context on O(6)-methylguanine repair and replication in vivo

Understanding the origins of mutational hotspots is complicated by the intertwining of several variables. The selective formation, repair, and replication of a DNA lesion, such as O(6)-methylguanine (m(6)G), can, in principle, be influenced by the surrounding nucleotide environment. A nearest-neighbor analysis was used to address the contribution of sequence context on m(6)G repair by the Escherichia coli methyltransferases Ada or Ogt, and on DNA polymerase infidelity in vivo. Sixteen M13 viral genomes with m(6)G flanked by all permutations of G, A, T, and C were constructed and individually transformed into repair-deficient and repair-proficient isogenic cell strains. The 16 genomes were introduced in duplicate into 5 different cellular backgrounds for a total of 160 independent experiments, for which mutations were scored using a recently developed assay. The Ada methyltransferase demonstrated strong 5' and 3' sequence-specific repair of m(6)G in vivo. The Ada 5' preference decreased in the general order: GXN > CXN > TXN > AXN (X = m(6)G, N = any base), while the Ada 3' preference decreased in the order: NX(T/C) > NX(G/A), with mutation frequencies (MFs) ranging from 35% to 90%. The Ogt methyltransferase provided MFs ranging from 10% to 25%. As was demonstrated by Ada, the Ogt methyltransferase repaired m(6)G poorly in an AXN context. When both methyltransferases were removed, the MF was nearly 100% for all sequence contexts, consistent with the view that the replicative DNA polymerase places T opposite m(6)G during replication irrespective of the local sequence environment.

15-mer DNA duplexes containing an abasic site are thermodynamically more stable with adjacent purines than with pyrimidines

Abasic site (AP)-containing duplexes, with flanking adenine (A) or cytosine (C) bases, were shown to be more stable with flanking A than with C bases [Sági, J., Hang, B., and Singer, B. (1999) Chem. Res. Toxicol. 12, 917-923]. We investigated whether the lower-magnitude destabilization by an AP site, with A neighbors, is a general effect of the purine versus the pyrimidine neighbors. Duplex stability, as compared to that of the corresponding control duplexes, was markedly decreased by the incorporation of the AP site (x) opposite any of the four bases. However, for the duplexes containing T, A, or C opposite the AP site, replacement of the symmetric doublet flanking pyrimidine bases with purines resulted in a smaller destabilization effect. The average stabilizing effect of the symmetric doublet purine neighbors of an AP site opposite T, A, or C bases was 3.2 degrees C (DeltaT(m)) and 1.3 kcal/mol (DeltaDeltaG degrees (37)) compared to those of pyrimidine neighbors. In contrast, a G.AP pair reduced or eliminated the differential effect of the neighbors. Using unrestrained molecular dynamics, it was shown that for the duplexes containing T opposite the AP site, with doublet pyrimidine neighbors, there was a larger magnitude of curvature around the lesion site than for the duplexes with the purines flanking the AP site. Purines flanking the AP site tend to shift toward each other, creating overlap, in contrast to the flanking pyrimidines. This indicates the possibility of stacking between purine bases at the AP site and can be the reason for the observed smaller thermodynamic destabilization of the duplexes with the AAxAA and GGxGG central sequences, as compared to those with TTxTT and CCxCC sequences. This work showed that for an AP site the GC content is not the only determinant of duplex stability, but rather is influenced more by whether purines or pyrimidines flank the AP site.

Sequence-dependent conformational perturbation in DNA duplexes containing an epsilonA.T mismatch using molecular dynamics simulation

Previous experiments from this laboratory showed that 1, N:(6)-ethenoadenine (epsilonA) in 15mer DNA oligonucleotide duplexes with GGepsilonAGG and CCepsilonACC central sequences is repaired 3-5-fold more efficiently than in duplexes containing AAepsilonAAA and TTepsilonATT central sequences. This sequence dependence in repair rates appeared to correlate with the observed thermodynamic stability of these duplexes [Hang et al. (1998) J. Biol. Chem., 273, 33406-33413]. In the present work, unrestrained molecular dynamics was used to evaluate the sequence-dependent structural features of these duplexes. Explicit solvent and the particle mesh Ewald method were applied for the accurate representation of the electrostatic interactions. The differences observed in the axis- and intra-base pair parameters were primarily localized at the epsilonA*T mismatch in all sequences and indicate conformational diversity between the structures. However, all four structures remained in the B-conformational family. In the tip, tilt and propeller twist parameters for the five central base pairs, larger perturbations were found for the two duplexes with epsilonA flanked by A or T bases than for duplexes with epsilonA flanked by G or C bases. As a result of these perturbations, the average global curvature of the AAepsilonAAA and TTvarepsilonATT DNA duplexes was larger by approximately 12 degrees than that of the duplexes with the GGepsilonAGG and CCepsilonACC central sequences. The observed conformational differences between the duplexes containing A or T and G or C neighbors of epsilonA may contribute to the observed differential enzymatic repair of the same sequences.

Deficiency of N-methylpurine-DNA-glycosylase expression in nonparenchymal cells, the target cell for vinyl chloride and vinyl fluoride

The ability to repair promutagenic damage resulting from exposure to carcinogens is a critical factor in determining quantitative relationships in carcinogenesis, including the target cell for neoplasia. One major pathway for the repair of alkylating agent-induced DNA damage involves removal of alkylated bases by N-methylpurine-DNA-glycosylase (MPG), the first enzyme in base excision repair. We have measured the expression level of MPG mRNA in liver, lung, and kidney of Sprague-Dawley rats as a function of age. A quantitative reverse transcriptase-polymerase chain reaction (QRT-PCR) method was used to measure cellular MPG mRNA. MPG mRNA was readily detectable in each tissue analyzed and the age-dependent and tissue specific expressions were not statistically different. The lowest amount of mRNA was measured in preweanling liver and the highest amounts were found in preweanling lung and kidney. Since MPG is reported to be responsible for excision of 1,N(6)-ethenoadenine and N(2),3-ethenoguanine, two promutagenic DNA adducts of vinyl chloride (VC) and vinyl fluoride (VF), we examined the regulation of this enzyme after carcinogen exposure. Expression of MPG was induced in rat liver by these carcinogens. In order to determine the repair capacity in different cell populations of liver, we measured MPG gene expression in isolated hepatocytes and nonparenchymal cells (NPC). The amount of MPG mRNA was 4.5-5 times higher in hepatocytes than in NPC of control rats. Induction of MPG expression was observed in hepatocytes of VF exposed-rats but not in NPC. The expression of MPG in NPC was only 15% of that of the hepatocytes from exposed rats. Western blots of MPG protein confirmed the cell type differences, but did not show increased protein in exposed vs. control liver and hepatocytes. Since metabolism of VC and VF requires CYP2E1, an enzyme exhibiting much greater activity in hepatocytes, formation of etheno adducts preferentially occurs in hepatocytes. These data suggest that cellular differences in the repair of N-alkylpurines may be a critical mechanism in the development of cell specificity in VC carcinogenesis.

Cisplatin adducts inhibit 1,N(6)-ethenoadenine repair by interacting with the human 3-methyladenine DNA glycosylase

The human 3-methyladenine DNA glycosylase (AAG) is a repair enzyme that removes a number of damaged bases from DNA, including adducts formed by some chemotherapeutic agents. Cisplatin is one of the most widely used anticancer drugs. Its success in killing tumor cells results from its ability to form DNA adducts and the cellular processes triggered by the presence of those adducts in DNA. Variations in tumor response to cisplatin may result from altered expression of cellular proteins that recognize cisplatin adducts. The present study focuses on the interaction between the cisplatin intrastrand cross-links and human AAG. Using site-specifically modified oligonucleotides containing each of the cisplatin intrastrand cross-links, we found that AAG readily recognized cisplatin adducts. The apparent dissociation constants for the 1, 2-d(GpG), the 1,2-d(ApG), and the 1,3-d(GpTpG) oligonucleotides were 115 nM, 71 nM, and 144 nM, respectively. For comparison, the apparent dissociation constant for an oligonucleotide containing a single 1,N(6)-ethenoadenine (epsilonA), which is repaired efficiently by AAG, was 26 nM. Despite the affinity of AAG for cisplatin adducts, AAG was not able to release any of these adducts from DNA. Furthermore, it was demonstrated that the presence of cisplatin adducts in the reactions inhibited the excision of epsilonA by AAG. These data suggest a previously unexplored dimension to the toxicological response of cells to cisplatin. We suggest that cisplatin adducts could titrate AAG away from its natural substrates, resulting in higher mutagenesis and/or cell death because of the persistence of AAG substrates in DNA.

Substrate specificity of human methylpurine DNA N-glycosylase

The activity of human methylpurine DNA N-glycosylase (hMPG) for major substrates was directly compared using two types of substrates, i.e., natural DNA and synthetic oligonucleotides. By the use of ARP assay detecting abasic sites in DNA, we first investigated the activity on the natural DNA substrates containing methylpurines, ethenopurines, or hypoxanthine (Hx) prepared by the conventional methods. After the treatment with hMPG, the amount of AP sites in methylated DNA was much higher than that in DNA containing ethenopurines or Hx. The oligodeoxynucleotide having a single 7-methylguanine (7-mG) was newly synthesized in addition to 1, N(6)-ethenoadenine (epsilonA)-, Hx-, and 8-oxoguanine-containing oligonucleotides. 7-mG was effectively excised by hMPG, though it might be less toxic than the other methylated bases with respect to mutagenesis and cell killing. The kinetic study demonstrated that k(cat)/K(m) ratios of the enzyme for epsilonA, Hx, and 7-mG were 2.5 x 10(-3), 1.4 x 10(-3), and 4 x 10(-4) min(-1) nM(-1), respectively. The oligonucleotides containing epsilonA effectively competed against 7-mG, while Hx substrates showed unexpectedly low competition. Concerning the effect of the base opposite damage, hMPG much preferred Hx.T to other Hx pairs, and epsilonA.C and epsilonA.A pairs were better substrates than epsilonA.T.

Distinct repair activities of human 7,8-dihydro-8-oxoguanine DNA glycosylase and formamidopyrimidine DNA glycosylase for formamidopyrimidine and 7,8-dihydro-8-oxoguanine

7,8-dihydro-8-oxoguanine (8-oxoG) and 2,6-diamino-4-hydroxyformamidopyrimidine (Fapy) are major DNA lesions formed by reactive oxygen species and are involved in mutagenic and/or lethal events in cells. Both lesions are repaired by human 7, 8-dihydro-8-oxoguanine DNA glycosylase (hOGG1) and formamidopyrimidine DNA glycosylase (Fpg) in human and Escherichia coli cells, respectively. In the present study, the repair activities of hOGG1 and Fpg were compared using defined oligonucleotides containing 8-oxoG and a methylated analog of Fapy (me-Fapy) at the same site. The k(cat)/K(m) values of hOGG1 for 8-oxoG and me-Fapy were comparable, and this was also the case for Fpg. However, the k(cat)/K(m) values of hOGG1 for both lesions were approximately 80-fold lower than those of Fpg. Analysis of the Schiff base intermediate by NaBH(4) trapping implied that lower substrate affinity and slower hydrolysis of the intermediate for hOGG1 than Fpg accounted for the difference. hOGG1 and Fpg showed distinct preferences of the base opposite 8-oxoG, with the activity differences being 19.8- (hOGG1) and 12-fold (Fpg) between the most and least preferred bases. Surprisingly, such preferences were almost abolished and less than 2-fold for both enzymes when me-Fapy was a substrate, suggesting that, unlike 8-oxoG, me-Fapy is not subjected to paired base-dependent repair. The repair efficiency of me-Fapy randomly incorporated in M13 DNA varied at the sequence level, but orders of preferred and unpreferred repair sites were quite different for hOGG1 and Fpg. The distinctive activities of hOGG1 and Fpg including enzymatic parameters (k(cat)/K(m)), paired base, and sequence context effects may originate from the differences in the inherent architecture of the DNA binding domain and catalytic mechanism of the enzymes.

Sequence-dependent repair of synthetic AP sites in 15-mer and 35-mer oligonucleotides: role of thermodynamic stability imposed by neighbor bases

We previously reported that 15-mer oligonucleotides with a central 1, N(6)-epsilonA were cleaved by alkylpurine-DNA N-glycosylase as a function of T(m), modulated by neighbor bases [Hang, B., Sági, J., and Singer, B. (1998) J. Biol. Chem. 273, 33406-33413]. This type of investigation has now been extended to cleavage by Escherichia coli endonuclease IV of a centrally placed synthetic AP site using both 15-mer and 35-mer duplexes. In 15-mers, the triplet sequences adjunct to the central AP site greatly affected the thermodynamic stability. The repair rate paralleled the thermal stability since endonuclease IV requires a double-stranded substrate. When the AP site-containing duplexes were 35-mers, there was also a general correlation between the thermostability and cleavage efficiency. However, the difference in the cleavage rates between different sequences was much less than with the 15-mers. Since the 35-mers were more than 96% annealed, this difference presumably results from local stability and structure adjacent to the AP site. These results suggest that under enzyme limiting conditions or overproduction of AP sites, sequence-dependent differential repair could occur in vivo.