Suppression of spontaneous mutagenesis in human cells by DNA base excision–repair

The chemical instability of the covalent structure of DNA, and in vivo exposure of DNA to reactive oxygen species and endogenously produced alkylating agents, has triggered the evolution of several specific DNA repair pathways. A major strategy of repair involves the initial removal of an altered base from DNA by a member of the enzyme family of DNA glycosylases. The currently known enzymes of this type in mammalian cells are reviewed, and the subsequent base excision–repair (BER) steps that achieve restoration of the intact DNA structure are also described. The specific problem of retaining high accuracy in this essentially error-free repair process is discussed.     

Structure and activity of a thermostable thymine-DNA glycosylase: evidence for base twisting to remove mismatched normal DNA bases.

The repair of T:G mismatches in DNA is key for maintaining bacterial restriction/modification systems and gene silencing in higher eukaryotes. T:G mismatch repair can be initiated by a specific mismatch glycosylase (MIG) that is homologous to the helix-hairpin-helix (HhH) DNA repair enzymes. Here, we present a 2.0 A resolution crystal structure and complementary mutagenesis results for this thermophilic HhH MIG enzyme. The results suggest that MIG distorts the target thymine nucleotide by twisting the thymine base approximately 90 degrees away from its normal anti position within DNA. We propose that functionally significant differences exist in DNA repair enzyme extrahelical nucleotide binding and catalysis that are characteristic of whether the target base is damaged or is a normal base within a mispair. These results explain why pure HhH DNA glycosylases and combined glycosylase/AP lyases cannot be interconverted by simply altering their functional group chemistry, and how broad-specificity DNA glycosylase enzymes may weaken the glycosylic linkage to allow a variety of damaged DNA bases to be excised.     

Solution structure and base perturbation studies reveal a novel mode of alkylated base recognition by 3-methyladenine DNA glycosylase I

The specific recognition mechanisms of DNA repair glycosylases that remove cationic alkylpurine bases in DNA are not well understood partly due to the absence of structures of these enzymes with their cognate bases. Here we report the solution structure of 3-methyladenine DNA glycosylase I (TAG) in complex with its 3-methyladenine (3-MeA) cognate base, and we have used chemical perturbation of the base in combination with mutagenesis of the enzyme to evaluate the role of hydrogen bonding and pi-cation interactions in alkylated base recognition by this DNA repair enzyme. We find that TAG uses hydrogen bonding with heteroatoms on the base, van der Waals interactions with the 3-Me group, and conventional pi-pi stacking with a conserved Trp side chain to selectively bind neutral 3-MeA over the cationic form of the base. Discrimination against binding of the normal base adenine is derived from direct sensing of the 3-methyl group, leading to an induced-fit conformational change that engulfs the base in a box defined by five aromatic side chains. These findings indicate that base specific recognition by TAG does not involve strong pi-cation interactions, and suggest a novel mechanism for alkylated base recognition and removal.     

DNA polymerases β and λ and their roles in cell

Among the set of mammalian DNA polymerases, DNA polymerases belonging to the X and Y families have a special place. The majority of these enzymes are involved in repair, including base excision repair and non-homologous end joining. Some of them play a crucial role during the specific process which is referred to as translesion synthesis (TLS). TLS intends for the cell surviving during the replication of damaged DNA templates. Additionally, specific activities of TLS-polymerases have to be useful for repair of double-stranded clustered lesions: if the synthesis is proceeded via base excision repair process, the role of DNA polymerases β or λ will be important. In this review we discussed the biochemical properties and functional relevance of X family DNA polymerases β and λ.     

Poxvirus uracil‐DNA glycosylase—An unusual member of the family I uracil‐DNA glycosylases

Uracil‐DNA glycosylases are ubiquitous enzymes, which play a key role repairing damages in DNA and in maintaining genomic integrity by catalyzing the first step in the base excision repair pathway. Within the superfamily of uracil‐DNA glycosylases family I enzymes or UNGs are specific for recognizing and removing uracil from DNA. These enzymes feature conserved structural folds, active site residues and use common motifs for DNA binding, uracil recognition and catalysis. Within this family the enzymes of poxviruses are unique and most remarkable in terms of amino acid sequences, characteristic motifs and more importantly for their novel non‐enzymatic function in DNA replication. UNG of vaccinia virus, also known as D4, is the most extensively characterized UNG of the poxvirus family. D4 forms an unusual heterodimeric processivity factor by attaching to a poxvirus‐specific protein A20, which also binds to the DNA polymerase E9 and recruits other proteins necessary for replication. D4 is thus integrated in the DNA polymerase complex, and its DNA‐binding and DNA scanning abilities couple DNA processivity and DNA base excision repair at the replication fork. The adaptations necessary for taking on the new function are reflected in the amino acid sequence and the three‐dimensional structure of D4. An overview of the current state of the knowledge on the structure‐function relationship of D4 is provided here.     

DNA base repair – recognition and initiation of catalysis

Endogenous DNA damage induced by hydrolysis, reactive oxygen species and alkylation modifies DNA bases and the structure of the DNA duplex. Numerous mechanisms have evolved to protect cells from these deleterious effects. Base excision repair is the major pathway for removing base lesions. However, several mechanisms of direct base damage reversal, involving enzymes such as transferases, photolyases and oxidative demethylases, are specialized to remove certain types of photoproducts and alkylated bases. Mismatch excision repair corrects for misincorporation of bases by replicative DNA polymerases. The determination of the 3D structure and visualization of DNA repair proteins and their interactions with damaged DNA have considerably aided our understanding of the molecular basis for DNA base lesion repair and genome stability. Here, we review the structural biochemistry of base lesion recognition and initiation of one-step direct reversal (DR) of damage as well as the multistep pathways of base excision repair (BER), nucleotide incision repair (NIR) and mismatch repair (MMR).     

Unique dynamic properties of DNA duplexes containing interstrand cross-links

Bifunctional DNA alkylating agents form a diverse assortment of covalent DNA interstrand cross-linked (ICL) structures that are potent cytotoxins. Because it is implausible that cells could possess distinct DNA repair systems for each individual ICL, it is believed that common structural and dynamic features of ICL damage are recognized, rather than specific structural characteristics of each cross-linking agent. Investigation of the structural and dynamic properties of ICLs that might be important for recognition has been complicated by heterogeneous incorporation of these lesions into DNA. To address this problem, we have synthesized and characterized several homogeneous ICL DNAs containing site-specific staggered N4-cytosine-ethyl-N4-cytosine cross-links. Staggered cross-links were introduced in two ways, in a manner that preserves the overall structure of B-form duplex DNA and in a manner that highly distorts the DNA structure, with the goal of understanding how structural and dynamic properties of diverse ICL duplexes might flag these sites for repair. Measurements of base pair opening dynamics in the B-form ICL duplex by (1)H NMR line width or imino proton solvent exchange showed that the guanine base opposite the cross-linked cytosine opened at least 1 order of magnitude more slowly than when in a control matched normal duplex. To a lesser degree, the B-form ICL also induced a decrease in base pair opening dynamics that extended from the site of the cross-link to adjacent base pairs. In contrast, the non-B-form ICL showed extensive conformational dynamics at the site of the cross-link, which extended over the entire DNA sequence. Because DNA duplexes containing the B-form and non-B-form ICL cross-links have both been shown to be incised when incubated in mammalian whole cell extracts, while a matched normal duplex is not, we conclude that intrinsic DNA dynamics is not a requirement for specific damage incision of these ICLs. Instead, we propose a general model in which destabilized ICL duplexes serve to energetically facilitate binding of DNA repair factors that must induce bubbles or other distortions in the duplex. However, the essential requirement for incision is an immobile Y-junction where the repair factors are stably bound at the site of the ICL, and the two DNA strands are unpaired.     

Human DNA polymerase beta initiates DNA synthesis during long-patch repair of reduced AP sites in DNA

Simple base damages are repaired through a short-patch base excision pathway where a single damaged nucleotide is removed and replaced. DNA polymerase beta (Pol beta) is responsible for the repair synthesis in this pathway and also removes a 5'-sugar phosphate residue by catalyzing a beta-elimination reaction. How ever, some DNA lesions that render deoxyribose resistant to beta-elimination are removed through a long-patch repair pathway that involves strand displacement synthesis and removal of the generated flap by specific endonuclease. Three human DNA polymerases (Pol beta, Pol delta and Pol epsilon) have been proposed to play a role in this pathway, however the identity of the polymerase involved and the polymerase selection mechanism are not clear. In repair reactions catalyzed by cell extracts we have used a substrate containing a reduced apurinic/apyrimidinic (AP) site resistant to beta-elimination and inhibitors that selectively affect different DNA polymerases. Using this approach we find that in human cell extracts Pol beta is the major DNA polymerase incorporating the first nucleotide during repair of reduced AP sites, thus initiating long-patch base excision repair synthesis.     

Three-dimensional structural views of damaged-DNA recognition: T4 endonuclease V, E. coli Vsr protein, and human nucleotide excision repair factor XPA

Genetic information is frequently disturbed by introduction of modified or mismatch bases into duplex DNA, and hence all organisms contain DNA repair systems to restore normal genetic information by removing such damaged bases or nucleotides and replacing them by correct ones. The understanding of this repair mechanism is a central subject in cell biology. This review focuses on the three-dimensional structural views of damaged DNA recognition by three proteins. The first protein is T4 endonuclease V (T4 endo V), which catalyzes the first reaction step of the excision repair pathway to remove pyrimidine-dimers (PD) produced within duplex DNA by UV irradiation. The crystal structure of this enzyme complexed with DNA containing a thymidine-dimer provided the first direct view of DNA lesion recognition by a repair enzyme, indicating that the DNA kink coupled with base flipping-out is important for damaged DNA recognition. The second is very short patch repair (Vsr) endonuclease, which recognizes a TG mismatch within the five base pair consensus sequence. The crystal structure of this enzyme in complex with duplex DNA containing a TG mismatch revealed a novel mismatch base pair recognition scheme, where three aromatic residues intercalate from the major groove into the DNA to strikingly deform the base pair stacking but the base flipping-out does not occur. The third is human nucleotide excision repair (NER) factor XPA, which is a major component of a large protein complex. This protein has been shown to bind preferentially to UV- or chemical carcinogen-damaged DNA. The solution structure of the XPA central domain, essential for the interaction of damaged DNA, was determined by NMR. This domain was found to be divided mainly into a (Cys)4-type zinc-finger motif subdomain for replication protein A (RPA) recognition and the carboxyl terminal subdomain responsible for DNA binding.     

5-Hydroxy-5-methylhydantoin DNA lesion, a molecular trap for DNA glycosylases

DNA base-damage recognition in the base excision repair (BER) is a process operating on a wide variety of alkylated, oxidized and degraded bases. DNA glycosylases are the key enzymes which initiate the BER pathway by recognizing and excising the base damages guiding the damaged DNA through repair synthesis. We report here biochemical and structural evidence for the irreversible entrapment of DNA glycosylases by 5-hydroxy-5-methylhydantoin, an oxidized thymine lesion. The first crystal structure of a suicide complex between DNA glycosylase and unrepaired DNA has been solved. In this structure, the formamidopyrimidine-(Fapy) DNA glycosylase from Lactococcus lactis (LlFpg/LlMutM) is covalently bound to the hydantoin carbanucleoside-containing DNA. Coupling a structural approach by solving also the crystal structure of the non-covalent complex with site directed mutagenesis, this atypical suicide reaction mechanism was elucidated. It results from the nucleophilic attack of the catalytic N-terminal proline of LlFpg on the C5-carbon of the base moiety of the hydantoin lesion. The biological significance of this finding is discussed.     

Base excision repair of DNA: glycosylases

The review considers the role of base excision repair in maintaining the constancy of genetic information in the cell. The genetic control and biochemical mechanism are described for the first stage of base excision repair, which is catalyzed by specific enzymes, DNA glycosylases.     

DNA glycosylase recognition and catalysis

DNA glycosylases are the enzymes responsible for recognizing base lesions in the genome and initiating base excision DNA repair. Recent structural and biochemical results have provided novel insights into DNA damage recognition and repair. The basis of the recognition of the oxidative lesion 8-oxoguanine by two structurally unrelated DNA glycosylases is now understood and has been revealed to involve surprisingly similar strategies. Work on MutM (Fpg) has produced structures representing three discrete reaction steps. The NMR structure of 3-methyladenine glycosylase I revealed its place among the structural families of DNA glycosylases and the X-ray structure of SMUG1 likewise confirmed that this protein is a member of the uracil DNA glycosylase superfamily. A novel disulfide cross-linking strategy was used to obtain the long-anticipated structure of MutY bound to DNA containing an A*oxoG mispair.     

Lack of effect of hydroxyurea on base excision repair in mammalian cells

The effect of hydroxyurea on the initial steps of base excision repair has been examined in mammalian cells in 3 different proliferative states: i.e., quiescent cells, asynchronously growing cells undergoing multiple divisions prior to confluence; and synchronous cell populations undergoing the first cell cycle(s) after release from quiescence. Two parameters of the base excision repair pathway were examined: (1) The direct excision of 7-methylguanine from cellular DNA in the presence of increasing hydroxyurea concentrations was quantitated by high performance liquid chromatography; (2) the effects of hydroxyurea on the uracil DNA glycosylase were examined by quantitating the levels of this base excision repair enzyme in quiescent and proliferating cells. In quiescent cells, hydroxyurea at concentrations routinely used to quantitate DNA repair had no effect on the excision rates of 7-methylguanine examined over a span of 3 days; nor was there any effect on the specific activity of uracil DNA glycosylase in confluent cells. In asynchronously proliferating mammalian cells, identical hydroxyurea concentrations had no effect on the induction of the glycosylase. In synchronous growing cells HU had no effect on the temporal sequence of induction of uracil DNA glycosylase prior to DNA replication, nor on the extent of this induction. These results suggest that hydroxyurea at concentrations generally used to measure DNA repair has no effect on base excision repair.     

Mono- and Bifunctional DNA Glycosylases Involved in Repairing Oxidatively Damaged DNA

DNA repair is a basic biological process providing for the stability and integrity of the genome. Disturbed repair results in premature aging, autoimmune and cardiological disorders, tumorigenesis, etc. Data on enzymes which play key roles in repairing DNA with lesions generated by reactive oxygen species are reviewed. The substrate specificity, mechanism of catalysis, structure of the active center, and specific structural and functional features are described for Escherichia coli mono- and bifunctional DNA glycosylases (endonuclease III, Fpg, MutY, endonuclease VIII, AlkA, MutT) and their prokaryotic and eukaryotic homologs (Ntg1, Ntg2, yOgg1, yOgg2, hOgg1, hOgg2, mOgg1, rOgg1, hMTH, hMYH, MAG, ADPG, and ANPG) which are involved in base excision repair.     

Resistance to Nucleotide Excision Repair of Bulky Guanine Adducts Opposite Abasic Sites in DNA Duplexes and Relationships between Structure and Function

The nucleotide excision repair of certain bulky DNA lesions is abrogated in some specific non-canonical DNA base sequence contexts, while the removal of the same lesions by the nucleotide excision repair mechanism is efficient in duplexes in which all base pairs are complementary. Here we show that the nucleotide excision repair activity in human cell extracts is moderate-to-high in the case of two stereoisomeric DNA lesions derived from the pro-carcinogen benzo[a]pyrene (cis- and trans-B[a]P-N ²-dG adducts) in a normal DNA duplex. By contrast, the nucleotide excision repair activity is completely abrogated when the canonical cytosine base opposite the B[a]P-dG adducts is replaced by an abasic site in duplex DNA. However, base excision repair of the abasic site persists. In order to understand the structural origins of these striking phenomena, we used NMR and molecular spectroscopy techniques to evaluate the conformational features of 11mer DNA duplexes containing these B[a]P-dG lesions opposite abasic sites. Our results show that in these duplexes containing the clustered lesions, both B[a]P-dG adducts adopt base-displaced intercalated conformations, with the B[a]P aromatic rings intercalated into the DNA helix. To explain the persistence of base excision repair in the face of the opposed bulky B[a]P ring system, molecular modeling results suggest how the APE1 base excision repair endonuclease, that excises abasic lesions, can bind productively even with the trans-B[a]P-dG positioned opposite the abasic site. We hypothesize that the nucleotide excision repair resistance is fostered by local B[a]P residue—DNA base stacking interactions at the abasic sites, that are facilitated by the absence of the cytosine partner base in the complementary strand. More broadly, this study sets the stage for elucidating the interplay between base excision and nucleotide excision repair in processing different types of clustered DNA lesions that are substrates of nucleotide excision repair or base excision repair mechanisms.     

Exchangeability of mammalian DNA ligases between base excision repair pathways

In mammalian cells, DNA ligase IIIalpha and DNA ligase I participate in the short- and long-patch base excision repair pathways, respectively. Using an in vitro repair assay employing DNA ligase-depleted cell extracts and DNA substrates containing a single lesion repaired either through short-patch (regular abasic site) or long-patch (reduced abasic site) base excision repair pathways, we addressed the question whether DNA ligases are specific to each pathway or if they are exchangeable. We find that immunodepletion of DNA ligase I did not affect the short-patch repair pathway but blocked long-patch repair, suggesting that DNA ligase IIIalpha is not able to substitute DNA ligase I during long-patch repair. In contrast, immunodepletion of DNA ligase IIIalpha did not significantly affect either pathway. Moreover, repair of normal abasic sites in wild-type and X-ray cross-complementing gene 1 (XRCC1)-DNA ligase IIIalpha-immunodepleted cell extracts involved similar proportions of short- and long-patch repair events. This suggests that DNA ligase I was able to efficiently substitute the XRCC1-DNA ligase IIIalpha complex during short-patch repair.     

DNA repair: models for damage and mismatch recognition

Maintaining the integrity of the genome is critical for the survival of any organism. To achieve this, many families of enzymatic repair systems which recognize and repair DNA damage have evolved. Perhaps most intriguing about the workings of these repair systems is the actual damage recognition process. What are the chemical characteristics which are common to sites of nucleic acid damage that DNA repair proteins may exploit in targeting sites? Importantly, thermodynamic and kinetic principles, as much as structural factors, make damage sites distinct from the native DNA bases, and indeed, in many cases, these are the features which are believed to be exploited by repair enzymes. Current proposals for damage recognition may not fulfill all of the demands required of enzymatic repair systems given the sheer size of many genomes, and the efficiency with which the genome is screened for damage. Here we discuss current models for how DNA damage recognition may occur and the chemical characteristics, shared by damaged DNA sites, of which repair proteins may take advantage. These include recognition based upon the thermodynamic and kinetic instabilities associated with aberrant sites. Additionally, we describe how small changes in base pair structure can alter also the unique electronic properties of the DNA base pair pi-stack. Further, we describe photophysical, electrochemical, and biochemical experiments in which mismatches and other local perturbations in structure are detected using DNA-mediated charge transport. Finally, we speculate as to how this DNA electron transfer chemistry might be exploited by repair enzymes in order to scan the genome for sites of damage.