DNA glycosylases in the base excision repair of DNA

Structure and specificity of the vertebrate anti-mutator uracil-DNA glycosylase SMUG1

Cytosine deamination is a major promutagenic process, generating G:U mismatches that can cause transition mutations if not repaired. Uracil is also introduced into DNA via nonmutagenic incorporation of dUTP during replication. In bacteria, uracil is excised by uracil-DNA glycosylases (UDG) related to E. coli UNG, and UNG homologs are found in mammals and viruses. Ung knockout mice display no increase in mutation frequency due to a second UDG activity, SMUG1, which is specialized for antimutational uracil excision in mammalian cells. Remarkably, SMUG1 also excises the oxidation-damage product 5-hydroxymethyluracil (HmU), but like UNG is inactive against thymine (5-methyluracil), a chemical substructure of HmU. We have solved the crystal structure of SMUG1 complexed with DNA and base-excision products. This structure indicates a more invasive interaction with dsDNA than observed with other UDGs and reveals an elegant water displacement/replacement mechanism that allows SMUG1 to exclude thymine from its active site while accepting HmU.

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

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

A novel uracil-DNA glycosylase family related to the helix-hairpin-helix DNA glycosylase superfamily

Cytosine bases can be deaminated spontaneously to uracil, causing DNA damage. Uracil-DNA glycosylase (UDG), a ubiquitous uracil-excising enzyme found in bacteria and eukaryotes, is one of the enzymes that repair this kind of DNA damage. To date, no UDG-coding gene has been identified in Methanococcus jannaschii, although its entire genome was deciphered. Here, we have identified and characterized a novel UDG from M.jannaschii designated as MjUDG. It efficiently removed uracil from both single- and double-stranded DNA. MjUDG also catalyzes the excision of 8-oxoguanine from DNA. MjUDG has a helix-hairpin-helix motif and a [4Fe-4S]-binding cluster that is considered to be important for the DNA binding and catalytic activity. Although MjUDG shares these features with other structural families such as endonuclease III and mismatch-specific DNA glycosylase (MIG), unique conserved amino acids and substrate specificity distinguish MjUDG from other families. Also, a homologous member of MjUDG was identified in Aquifex aeolicus. We report that MjUDG belongs to a novel UDG family that has not been described to date.

Differential incorporation of uracil DNA glycosylase UNG2 into HIV-1, HIV-2, and SIV(MAC) viral particles

We have previously reported that the host uracil DNA glycosylase UNG2 enzyme is incorporated into HIV-1 virions via a specific association with the viral integrase (IN) domain of Gag-Pol precursor. In this study, we investigated whether UNG2 was packaged into two phylogenetically closely related primate lentiviruses, HIV-2(ROD) and SIV(MAC239). We demonstrated by GST-pull-down and coprecipitation assays that INs from HIV-1, HIV-2(ROD), and SIV(MAC239) associated with UNG2, although the interaction of UNG2 with HIV-2(ROD) IN and SIV(MAC239) IN was less strong than with HIV-1 IN. We then showed by Western blotting that highly purified HIV-2 and SIV(MAC) viral particles did not incorporate host UNG2, contrasting with the presence of UNG2 in HIV-1 viral particles. Finally, we showed that HIV-1/SIV chimeric viruses in which residues 6 to 202 of HIV-1 IN were replaced by the SIV counterpart were impaired for packaging of UNG2, indicating that the incorporation of host UNG2 into viral particles is the hallmark of the HIV-1 strain. Moreover, we found that HIV-1/SIV IN chimeric viruses were deficient for viral propagation.

The main role of human thymine-DNA glycosylase is removal of thymine produced by deamination of 5-methylcytosine and not removal of ethenocytosine

Metabolites of vinyl chloride react with cytosine in DNA to form 3,N(4)-ethenocytosine. Recent studies suggest that ethenocytosine is repaired by the base excision repair pathway with the ethenobase being removed by thymine-DNA glycosylase. Here single turnover kinetics have been used to compare the excision of ethenocytosine by thymine-DNA glycosylase with the excision of thymine. The effect of flanking DNA sequence on the excision of ethenocytosine was also investigated. The 34-bp duplexes studied here fall into three categories. Ethenocytosine base-paired with guanine within a CpG site (i.e. CpG.(epsilon)C-DNA) was by far the best substrate having a specificity constant (k(2)/K(d)) of 25.1 x 10(6) m(-1) s(-1). The next best substrates were DNA duplexes containing TpG.(epsilon)C, GpG.(epsilon)C, and CpG.T. These had specificity constants 45-130 times smaller than CpG.(epsilon)C-DNA. The worst substrates were DNA duplexes containing ApG.(epsilon)C and TpG.T, which had specificity constants, respectively, 1,600 and 7,400 times lower than CpG.(epsilon)C-DNA. DNA containing ethenocytosine was bound much more tightly than DNA containing a G.T mismatch. This is probably because thymine-DNA glycosylase can flip out ethenocytosine from a G.(epsilon)C base pair more easily than it can flip out thymine from a G.T mismatch. Because thymine-DNA glycosylase has a larger specificity constant for the removal of ethenocytosine, it has been suggested its primary purpose is to deal with ethenocytosine. However, these results showing that thymine-DNA glycosylase has a strong sequence preference for CpG sites in the excision of both thymine and ethenocytosine suggest that the main role of thymine-DNA glycosylase in vivo is the removal of thymine produced by deamination of 5-methylcytosine at CpG sites.

In vitro genotoxicity of lead acetate: induction of single and double DNA strand breaks and DNA-protein cross-links

Lead is present in the natural and occupational environment and is reported to interact with DNA, but the mechanism of this interaction is not fully understood. Using the alkaline comet assay we showed that lead acetate at 1-100 microM induced DNA damage in isolated human lymphocytes measured the change in the comet tail length. At 1 and 10 microM we observed an increase in the tail length, whereas at 100 microM a decrease was seen. The former effect could follow from the induction of DNA strand breaks and/or alkali-labile sites (ALS), the latter from the formation of DNA-DNA and/or DNA-protein cross-links. No difference was observed between tail length for the alkaline and pH 12.1 versions of the assay, which indicates that strand breaks and not ALS are responsible for the tail length increase induced by lead. The neutral version of the test revealed that lead acetate induced DNA double-strand breaks at all concentrations tested. The presence of spin traps, 5,5-dimethyl-pyrroline N-oxide (DMPO) and N-tert-butyl-alpha-phenylnitrone (PBN) did not influence the level of DNA damage induced by lead. Post-treatment of the lead-damaged DNA (at 100 microM treatment concentration) by endonuclease III (Endo III) and formamidopyrimidine-DNA glycosylase (Fpg), enzymes recognizing oxidized DNA bases, as well as 3-methyladenine-DNA glycosylase II, an enzyme recognizing alkylated bases, gave rise to a significant increase in the extent of DNA damage. Proteinase K caused an increase in comet tail length, suggesting that lead acetate might cross-link DNA with nuclear proteins. Vitamin A, E, C, calcium chloride and zinc chloride acted synergistically on DNA damage evoked by lead. The results obtained suggest that lead acetate may induce single-strand breaks (SSB) and double-strand breaks (DSB) in DNA as well as DNA-protein cross-links. The participation of free radicals in DNA-damaging potential of lead is not important and it concerns other reactive species than could be trapped by DMPO or PBN.

Product-assisted catalysis in base-excision DNA repair

Most spontaneous damage to bases in DNA is corrected through the action of the base-excision DNA repair pathway. Base excision repair is initiated by DNA glycosylases, lesion-specific enzymes that intercept aberrant bases in DNA and catalyze their excision. How such proteins accomplish the feat of catalyzing no fewer than five sequential reaction steps using a single active site has been unknown. To help answer this, we report the structure of a trapped catalytic intermediate in DNA repair by human 8-oxoguanine DNA glycosylase. This structure and supporting biochemical results reveal that the enzyme sequesters the excised lesion base and exploits it as a cofactor to participate in catalysis. To our knowledge, the present example represents the first documented case of product-assisted catalysis in an enzyme-catalyzed reaction.

Massive parallelism, randomness and genomic advances

In reviewing the past decade, it is clear that genomics was, and still is, driven by innovative technologies, perhaps more so than any other scientific area in recent memory. From the outset, computing, mathematics and new automated laboratory techniques have been key components in allowing the field to move forward rapidly. We highlight some key innovations that have come together to nurture the explosive growth that makes a new era of genomics a reality. We also document how these new approaches have fueled further innovations and discoveries.

Age-associated decrease of oxidative repair enzymes, human 8-oxoguanine DNA glycosylases (hOgg1), in human aging

8-Oxoguanine has been shown to be a dominant cause of oxidative DNA damage by oxygen free radicals in eukaryotic cells. The 8-oxoguanine repair-specific enzyme 8-oxoguanine-DNA glycosylase (hOgg1) was recently cloned and was observed to conduct mainly short-patch base-excision repair. It has also been suggested that reactive oxygen species play an important role in the cellular aging process. We explored the association between the hOgg1 enzyme activity in somatic cells of human subjects of various ages and the role of hOgg1(326) genetic polymorphism. An 8-oxoguanine-containing 28 mer oligonucleotide was end-labeled with gamma-32P ATP and incubated with protein extracts from peripheral blood lymphocytes (PBL) from 78 healthy individuals ranging in age from newborn to 91 years old. The hOgg1 repair activity toward the radiolabelled 8-oxoguanine-containing DNA was determined, and the results indicated a significant age-dependent decrease in the hOgg1 activity in their lymphocytes. Significantly reduced activity was also shown in those with Cysteine/Cysteine genotypes. The genders of the subjects were not shown to be associated. These results provide an important observation regarding the cellular hOgg1 activity in somatic cells during the normal human aging processes.

The transcriptional response after oxidative stress is defective in Cockayne syndrome group B cells

Cockayne syndrome (CS) is a human hereditary disease belonging to the group of segmental progerias, and the clinical phenotype is characterized by postnatal growth failure, neurological dysfunction, cachetic dwarfism, photosensitivity, sensorineural hearing loss, and retinal degradation. CS-B cells are defective in transcription-coupled DNA repair, base excision repair, transcription, and chromatin structural organization. Using array analysis, we have examined the expression profile in CS complementation group B (CS-B) fibroblasts after exposure to oxidative stress (H2O2) before and after complete complementation with the CSB gene. The following isogenic cell lines were compared: CS-B cells (CS-B null), CS-B cells complemented with wild-type CSB (CS-B wt), and a stably transformed cell line with a point mutation in the ATPase domain of CSB (CS-B ATPase mutant). In the wt rescued cells, we detected significant induction (two-fold) of 112 genes out of the 6912 analysed. The patterns suggested an induction or upregulation of genes involved in several DNA metabolic processes including DNA repair, transcription, and signal transduction. In both CS-B mutant cell lines, we found a general deficiency in transcription after oxidative stress, suggesting that the CSB protein influenced the regulation of transcription of certain genes. Of the 6912 genes, 122 were differentially regulated by more than two-fold. Evidently, the ATPase function of CSB is biologically important as the deficiencies seen in the ATPase mutant cells are very similar to those observed in the CS-B-null cells. Some major defects are in the transcription of genes involved in DNA repair, signal transduction, and ribosomal functions.

Functional role of HIV-1 virion-associated uracil DNA glycosylase 2 in the correction of G:U mispairs to G:C pairs

Human monocytes/macrophages are target cells for HIV-1 infection. As other non-dividing cells, they are characterized by low and imbalanced intracellular dNTP pool levels and an excess of dUTP. The replication of HIV-1 in this cellular context favors misincorporation of uracil residues into viral DNA because of the use of dUTP in place of dCTP. We have previously reported that the host uracil DNA glycosylase enzyme UNG2 is packaged into HIV-1 viral particles via a specific association with the integrase domain of the Gag-Pol precursor. In this study, we investigated whether virion-associated UNG2 plays a role similar to that of its cellular counterpart. We show that the L172A mutation of integrase impaired the packaging of UNG2 into viral particles. Using a primer-template DNA substrate containing G:U mispairs, we demonstrate that wild-type viral lysate has the ability to repair G:U mismatched pairs to G:C matched pairs, in contrast to UNG2-deficient viral lysate. Moreover, no correction of G:T mispairs by wild-type HIV-1 viral lysate was observed, which argues for the specificity of the repair process. We also show that UNG2 physically associates with the viral reverse transcriptase enzyme. Altogether our data indicate for the first time that a uracil repair pathway is specifically associated with HIV-1 viral particles. However, the molecular mechanism of this process remains to be characterized further.

Kinetics and binding of the thymine-DNA mismatch glycosylase, Mig-Mth, with mismatch-containing DNA substrates

We have examined the removal of thymine residues from T-G mismatches in DNA by the thymine-DNA mismatch glycosylase from Methanobacterium thermoautrophicum (Mig-Mth), within the context of the base excision repair (BER) pathway, to investigate why this glycosylase has such low activity in vitro. Using single-turnover kinetics and steady-state kinetics, we calculated the catalytic and product dissociation rate constants for Mig-Mth, and determined that Mig-Mth is inhibited by product apyrimidinic (AP) sites in DNA. Electrophoretic mobility shift assays (EMSA) provide evidence that the specificity of product binding is dependent upon the base opposite the AP site. The binding of Mig-Mth to DNA containing the non-cleavable substrate analogue difluorotoluene (F) was also analyzed to determine the effect of the opposite base on Mig-Mth binding specificity for substrate-like duplex DNA. The results of these experiments support the idea that opposite strand interactions play roles in determining substrate specificity. Endonuclease IV, which cleaves AP sites in the next step of the BER pathway, was used to analyze the effect of product removal on the overall rate of thymine hydrolysis by Mig-Mth. Our results support the hypothesis that endonuclease IV increases the apparent activity of Mig-Mth significantly under steady-state conditions by preventing reassociation of enzyme to product.

Forespore-specific expression of Bacillus subtilis yqfS, which encodes type IV apurinic/apyrimidinic endonuclease, a component of the base excision repair pathway

The temporal and spatial expression of the yqfS gene of Bacillus subtilis, which encodes a type IV apurinic/apyrimidinic endonuclease, was studied. A reporter gene fusion to the yqfS opening reading frame revealed that this gene is not transcribed during vegetative growth but is transcribed during the last steps of the sporulation process and is localized to the developing forespore compartment. In agreement with these results, yqfS mRNAs were mainly detected by both Northern blotting and reverse transcription-PCR, during the last steps of sporulation. The expression pattern of the yqfS-lacZ fusion suggested that yqfS may be an additional member of the Esigma(G) regulon. A primer extension product mapped the transcriptional start site of yqfS, 54 to 55 bp upstream of translation start codon of yqfS. Such an extension product was obtained from RNA samples of sporulating cells but not from those of vegetatively growing cells. Inspection of the nucleotide sequence lying upstream of the in vivo-mapped transcriptional yqfS start site revealed the presence of a sequence with good homology to promoters preceding genes of the sigma(G) regulon. Although yqfS expression was temporally regulated, neither oxidative damage (after either treatment with paraquat or hydrogen peroxide) nor mitomycin C treatment induced the transcription of this gene.

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.

Uracil in DNA--occurrence, consequences and repair

Uracil in DNA results from deamination of cytosine, resulting in mutagenic U : G mispairs, and misincorporation of dUMP, which gives a less harmful U : A pair. At least four different human DNA glycosylases may remove uracil and thus generate an abasic site, which is itself cytotoxic and potentially mutagenic. These enzymes are UNG, SMUG1, TDG and MBD4. The base excision repair process is completed either by a short patch- or long patch pathway, which largely use different proteins. UNG2 is a major nuclear uracil-DNA glycosylase central in removal of misincorporated dUMP in replication foci, but recent evidence also indicates an important role in repair of U : G mispairs and possibly U in single-stranded DNA. SMUG1 has broader specificity than UNG2 and may serve as a relatively efficient backup for UNG in repair of U : G mismatches and single-stranded DNA. TDG and MBD4 may have specialized roles in the repair of U and T in mismatches in CpG contexts. Recently, a role for UNG2, together with activation induced deaminase (AID) which generates uracil, has been demonstrated in immunoglobulin diversification. Studies are now underway to examine whether mice deficient in Ung develop lymphoproliferative malignancies and have a different life span.

ROS1, a repressor of transcriptional gene silencing in Arabidopsis, encodes a DNA glycosylase/lyase

Mutations in the Arabidopsis ROS1 locus cause transcriptional silencing of a transgene and a homologous endogenous gene. In the ros1 mutants, the promoter of the silenced loci is hypermethylated, which may be triggered by small RNAs produced from the transgene repeats. The transcriptional silencing in ros1 mutants can be released by the ddm1 mutation or the application of the DNA methylation inhibitor 5-aza-2'-deoxycytidine. ROS1 encodes an endonuclease III domain nuclear protein with bifunctional DNA glycosylase/lyase activity against methylated but not unmethylated DNA. The ros1 mutant shows enhanced sensitivity to genotoxic agents methyl methanesulfonate and hydrogen peroxide. We suggest that ROS1 is a DNA repair protein that represses homology-dependent transcriptional gene silencing by demethylating the target promoter DNA.

Mitochondrial DNA repair and aging

The mitochondrial electron transport chain plays an important role in energy production in aerobic organisms and is also a significant source of reactive oxygen species that damage DNA, RNA and proteins in the cell. Oxidative damage to the mitochondrial DNA is implicated in various degenerative diseases, cancer and aging. The importance of mitochondrial ROS in age-related degenerative diseases is further strengthened by studies using animal models, Caenorhabditis elegans, Drosophila and yeast. Research in the last several years shows that mitochondrial DNA is more susceptible to various carcinogens and ROS when compared to nuclear DNA. DNA damage in mammalian mitochondria is repaired by base excision repair (BER). Studies have shown that mitochondria contain all the enzymes required for BER. Mitochondrial DNA damage, if not repaired, leads to disruption of electron transport chain and production of more ROS. This vicious cycle of ROS production and mtDNA damage ultimately leads to energy depletion in the cell and apoptosis.

Role of base flipping in specific recognition of damaged DNA by repair enzymes

DNA repair enzymes induce base flipping in the process of damage recognition. Endonuclease V initiates the repair of cis, syn thymine dimers (TD) produced in DNA by UV radiation. The enzyme is known to flip the base opposite the damage into a non-specific binding pocket inside the protein. Uracil DNA glycosylase removes a uracil base from G.U mismatches in DNA by initially flipping it into a highly specific pocket in the enzyme. The contribution of base flipping to specific recognition has been studied by molecular dynamics simulations on the closed and open states of undamaged and damaged models of DNA. Analysis of the distributions of bending and opening angles indicates that enhanced base flipping originates in increased flexibility of the damaged DNA and the lowering of the energy difference between the closed and open states. The increased flexibility of the damaged DNA gives rise to a DNA more susceptible to distortions induced by the enzyme, which lowers the barrier for base flipping. The free energy profile of the base-flipping process was constructed using a potential of mean force representation. The barrier for TD-containing DNA is 2.5 kcal mol(-1) lower than that in the undamaged DNA, while the barrier for uracil flipping is 11.6 kcal mol(-1) lower than the barrier for flipping a cytosine base in the undamaged DNA. The final barriers for base flipping are approximately 10 kcal mol(-1), making the rate of base flipping similar to the rate of linear scanning of proteins on DNA. These results suggest that damage recognition based on lowering the barrier for base flipping can provide a general mechanism for other DNA-repair enzymes.

AP endonuclease 1 coordinates flap endonuclease 1 and DNA ligase I activity in long patch base excision repair

Base loss is common in cellular DNA, resulting from spontaneous degradation and enzymatic removal of damaged bases. Apurinic/apyrimidinic (AP) endonucleases recognize and cleave abasic (AP) sites during base excision repair (BER). APE1 (REF1, HAP1) is the predominant AP endonuclease in mammalian cells. Here we analyzed the influences of APE1 on the human BER pathway. Specifically, APE1 enhanced the enzymatic activity of both flap endonuclease1 (FEN1) and DNA ligase I. FEN1 was stimulated on all tested substrates, regardless of flap length. Interestingly, we have found that APE1 can also inhibit the activities of both enzymes on substrates with a tetrahydrofuran (THF) residue on the 5'-downstream primer of a nick, simulating a reduced abasic site. However once the THF residue was displaced at least a single nucleotide, stimulation of FEN1 activity by APE1 resumes. Stimulation of DNA ligase I required the traditional nicked substrate. Furthermore, APE1 was able to enhance overall product formation in reconstitution of BER steps involving FEN1 cleavage followed by ligation. Overall, APE1 both stimulated downstream components of BER and prevented a futile cleavage and ligation cycle, indicating a far-reaching role in BER.

Methylpurine DNA glycosylase of the hyperthermophilic archaeon Archaeoglobus fulgidus

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

hUNG2 is the major repair enzyme for removal of uracil from U:A matches, U:G mismatches, and U in single-stranded DNA, with hSMUG1 as a broad specificity backup

hUNG2 and hSMUG1 are the only known glycosylases that may remove uracil from both double- and single-stranded DNA in nuclear chromatin, but their relative contribution to base excision repair remains elusive. The present study demonstrates that both enzymes are strongly stimulated by physiological concentrations of Mg2+, at which the activity of hUNG2 is 2-3 orders of magnitude higher than of hSMUG1. Moreover, Mg2+ increases the preference of hUNG2 toward uracil in ssDNA nearly 40-fold. APE1 has a strong stimulatory effect on hSMUG1 against dsU, apparently because of enhanced dissociation of hSMUG1 from AP sites in dsDNA. hSMUG1 also has a broader substrate specificity than hUNG2, including 5-hydroxymethyluracil and 3,N(4)-ethenocytosine. hUNG2 is excluded from, whereas hSMUG1 accumulates in, nucleoli in living cells. In contrast, only hUNG2 accumulates in replication foci in the S-phase. hUNG2 in nuclear extracts initiates base excision repair of plasmids containing either U:A and U:G in vitro. Moreover, an additional but delayed repair of the U:G plasmid is observed that is not inhibited by neutralizing antibodies against hUNG2 or hSMUG1. We propose a model in which hUNG2 is responsible for both prereplicative removal of deaminated cytosine and postreplicative removal of misincorporated uracil at the replication fork. We also provide evidence that hUNG2 is the major enzyme for removal of deaminated cytosine outside of replication foci, with hSMUG1 acting as a broad specificity backup.

Long-patch base excision repair of apurinic/apyrimidinic site DNA is decreased in mouse embryonic fibroblast cell lines treated with plumbagin: involvement of cyclin-dependent kinase inhibitor p21Waf-1/Cip-1

Molecular interactions among cell cycle and DNA repair proteins have been described, but the impact of many of these interactions on cell cycle control and DNA repair remains unclear. The cyclin-dependent kinase inhibitor, p21, is known to be involved in DNA damage-induced cell cycle arrest and blocking DNA replication and repair. Participation of p21 has been implicated in nucleotide excision repair. However, the role of p21 in the base excision repair (BER) pathway has not been thoroughly studied. In the present investigation, we treated isogenic mouse embryonic fibroblast (MEF) cell lines containing wild-type (MEF-polbeta) or DNA polymerase beta (polbeta) gene-knockout (MEFpolbetaKO) with oxidative DNA-damaging agent, plumbagin, and examined its effect on p21 levels and BER activity. Plumbagin treatment caused a S-G(2)/M phase arrest and cell death of both MEF cell lines, induced p21 levels, and decreased p21-mediated long-patch (LP) BER by blocking DNA ligase activity in the polbeta-dependent pathway and by blocking both FEN1 and DNA ligase activity in polbeta-independent pathway. These findings suggest that plumbagin induced p21 levels play a regulatory role in cell cycle arrest, apoptosis, and polbeta-dependent and -independent LP-BER pathways in MEF cells.

Mutational analysis of the uracil DNA glycosylase inhibitor protein and its interaction with Escherichia coli uracil DNA glycosylase

Uracil DNA glycosylase inhibitor (Ugi), a protein of 9.4 kDa consists of a five-stranded antiparallel beta sheet flanked on either side by single alpha helices, forms an exclusive complex with uracil DNA glycosylases (UDGs) that is stable in 8M urea. We report on the mutational analysis of various structural elements in Ugi, two of which (hydrophobic pocket and the beta1 edge) establish key interactions with Escherichia coli UDG. The point mutations in helix alpha1 (amino acid residues 3-14) do not affect the stability of the UDG-Ugi complexes in urea. And, while the complex of the deltaN13 mutant with UDG is stable in only approximately 4M urea, its overall structure and thermostability are maintained. The identity of P37, stacked between P26 and W68, was not important for the maintenance of the hydrophobic pocket or for the stability of the complex. However, the M24K mutation at the rim of the hydrophobic pocket lowered the stability of the complex in 6M urea. On the other hand, non-conservative mutations E49G, D61G (cancels the only ionic interaction with UDG) and N76K, in three of the loops connecting the beta strands, conferred no such phenotype. The L23R and S21P mutations (beta1 edge) at the UDG-Ugi interface, and the N35D mutation far from the interface resulted in poor stability of the complex. However, the stability of the complexes was restored in the L23A, S21T and N35A mutations. These analyses and the studies on the exchange of Ugi mutants in preformed complexes with the substrate or the native Ugi have provided insights into the two-step mechanism of UDG-Ugi complex formation. Finally, we discuss the application of the Ugi isolates in overproduction of UDG mutants, toxic to cells.

Truncation of amino-terminal tail stimulates activity of human endonuclease III (hNTH1)

The human base excision repair enzyme hNTH1, a homologue of Escherichia coli endonuclease III (Nth), is a 36kDa DNA glycosylase with associated abasic (AP) lyase activity. It has significant sequence homology with Nth in its DNA-binding motifs and catalytic residues but possesses a unique amino (N)-terminal tail (residues 1-95). We investigated the structure and function of this tail. Controlled proteolysis cleaved hNTH1 into discrete fragments to generate a 25kDA core domain lacking the N-terminal 98 residues. Surprisingly, recombinant hNTH1 lacking 55, 72 or 80 residues from the N terminus had four- to fivefold higher activities than the full-length enzyme. Kinetic analysis at transition states revealed that release of the final product, an AP site with a 3'-nick, is the rate-limiting step in the multi-step reaction mediated by hNTH1. The N-terminal tail regulates its overall catalytic turnover by reducing this product release rate by five- to sevenfold without affecting either the glycosylase or AP lyase activities, or the steady-state equilibrium concentration of Schiff base intermediate, the covalent complex of hNTH1 and AP-site DNA formed after the base is excised. The inhibitory role of the N-terminal tail in catalytic turnover explains the low activity of hNTH1 compared to that of its E.coli homologue.

Substrate recognition by a family of uracil-DNA glycosylases: UNG, MUG, and TDG

In response to continuous hydrolytic and oxidative DNA damage, cells of all organisms have a complex network of repair systems that recognize, remove, and rebuild the injured sites. Damaged pyrimidines are generally removed by glycosylases that must scan the entire genome to locate lesions with sufficient fidelity to selectively remove the damage without inadvertent removal of normal bases. We report here studies conducted with a series of base analogues designed to test mechanisms of base recognition suggested by structural studies of glycosylase complexes. The oligonucleotide series examined here includes 5-halouracils with increasing substituent size and purine analogues placed opposite the target uracil with hydrogen, amino, and keto substituents in the 2- and 6-positions. The glycosylases studied here include Escherichia coli uracil-DNA glycosylase (UNG), E. coli mismatch uracil-DNA glycosylase (MUG), and the Methanobacterium thermoautotrophicum mismatch thymine-DNA glycosylase (TDG). The results of this study suggest that these glycosylases utilize several strategies for base identification, including (1) steric limitations on the size of the 5-substituent, (2) electronic-inductive properties of the 5-substituent, (3) reduced thermal stability of mispairs, and (4) specific functional groups on the purine base in the opposing strand. Contrary to predictions based upon the crystal structure, the preference of MUG for mispaired uracil over thymine is not based upon steric exclusion. Furthermore, the preference for mispaired uracil over uracil paired with adenine is more likely due to reduced thermal stability as opposed to specific recognition of the mispaired guanine. On the other hand, TDG, which exhibits modest discrimination among various pyrimidines, shows strong interactions with functional groups present on the purine opposite the target pyrimidine. These results provide new insights into the mechanisms of base selection by DNA repair glycosylases.

Effects of mutations at tyrosine 66 and asparagine 123 in the active site pocket of Escherichia coli uracil DNA glycosylase on uracil excision from synthetic DNA oligomers: evidence for the occurrence of long-range interactions between the enzyme and substrate

Uracil DNA glycosylase (UDG), a highly conserved DNA repair enzyme, excises uracil from DNA. Crystal structures of several UDGs have identified residues important for their exquisite specificity in detection and removal of uracil. Of these, Y66 and N123 in Escherichia coli UDG have been proposed to restrict the entry of non-uracil residues into the active site pocket. In this study, we show that the uracil excision activity of the Y66F mutant was similar to that of the wild-type protein, whereas the activities of the other mutants (Y66C, Y66S, N123D, N123E and N123Q) were compromised approximately 1000-fold. The latter class of mutants showed an increased dependence on the substrate chain length and suggested the existence of long-range interactions of the substrate with UDG. Investigation of the phosphate interactions by the ethylation interference assay reaffirmed the key importance of the -1, +1 and +2 phosphates (with respect to the scissile uracil) to the enzyme activity. Interestingly, this assay also revealed an additional interference at the -5 position phosphate, whose presence in the substrate had a positive effect on substrate utilisation by the mutants that do not possess a full complement of interactions in the active site pocket. Such long-range interactions may be crucial even for the wild-type enzyme under in vivo conditions. Further, our results suggest that the role of Y66 and N123 in UDG is not restricted merely to preventing the entry of non-uracil residues. We discuss their additional roles in conferring stability to the transition state enzyme-substrate complex and/or enhancing the leaving group quality of the uracilate anion during catalysis.

DEMETER, a DNA glycosylase domain protein, is required for endosperm gene imprinting and seed viability in arabidopsis

We isolated mutations in Arabidopsis to understand how the female gametophyte controls embryo and endosperm development. For the DEMETER (DME) gene, seed viability depends only on the maternal allele. DME encodes a large protein with DNA glycosylase and nuclear localization domains. DME is expressed primarily in the central cell of the female gametophyte, the progenitor of the endosperm. DME is required for maternal allele expression of the imprinted MEDEA (MEA) Polycomb gene in the central cell and endosperm. Ectopic DME expression in endosperm activates expression of the normally silenced paternal MEA allele. In leaf, ectopic DME expression induces MEA and nicks the MEA promoter. Thus, a DNA glycosylase activates maternal expression of an imprinted gene in the central cell.

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.

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

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

Distinct gene expression signatures in the striata of wild-type and heterozygous c-fos knockout mice following methamphetamine administration: evidence from cDNA array analyses

Methamphetamine (METH) is a drug of abuse which can cause apoptosis and degeneration of monoaminergic terminals in the mammalian brain. c-fos appears to play a protective role against METH-induced damage because METH toxicity is exacerbated in c-fos heterozygous knockout mice. In the present study, we used the comprehensive technique of cDNA array to test the idea that heterozygous c-fos knockout mice might show differential METH-induced molecular responses in comparison to wild-type (WT) animals. Of 1,176 genes examined, the expression of 195 genes in either of the two groups of mice was affected by at least 2-fold at 2 or 12 h after METH treatment. More genes were either up- or downregulated in the WT mice. Moreover, there were substantial differences in the pattern of responses between the two genotypes, with more genes involved in DNA repair and protective processes being upregulated in WT mice after METH administration. These results support the idea that the c-fos knockout genotype may render the animals unable to trigger multicomponent responses in order to protect against the multifaceted toxic effects of this illicit neurotoxin.

Endogenous DNA abasic sites cause cell death in the absence of Apn1, Apn2 and Rad1/Rad10 in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, mutations in APN1, APN2 and either RAD1 or RAD10 genes are synthetic lethal. In fact, apn1 apn2 rad1 triple mutants can form microcolonies of approximately 300 cells. Expression of Nfo, the bacterial homologue of Apn1, suppresses the lethality. Turning off the expression of Nfo induces G(2)/M cell cycle arrest in an apn1 apn2 rad1 triple mutant. The activation of this checkpoint is RAD9 dependent and allows residual DNA repair. The Mus81/Mms4 complex was identified as one of these back-up repair activities. Furthermore, inactivation of Ntg1, Ntg2 and Ogg1 DNA N-glycosylase/AP lyases in the apn1 apn2 rad1 background delayed lethality, allowing the formation of minicolonies of approximately 10(5) cells. These results demonstrate that, under physiological conditions, endogenous DNA damage causes death in cells deficient in Apn1, Apn2 and Rad1/Rad10 proteins. We propose a model in which endogenous DNA abasic sites are converted into 3'-blocked single-strand breaks (SSBs) by DNA N-glycosylases/AP lyases. Therefore, we suggest that the essential and overlapping function of Apn1, Apn2, Rad1/Rad10 and Mus81/Mms4 is to repair 3'-blocked SSBs using their 3'-phosphodiesterase activity or their 3'-flap endonuclease activity, respectively.

Biochemical properties of single-stranded DNA-binding protein from Mycobacterium smegmatis, a fast-growing mycobacterium and its physical and functional interaction with uracil DNA glycosylases

The single-stranded DNA-binding proteins (SSBs) are vital to virtually all DNA functions. Here, we report on the biochemical properties of SSB from a fast-growing mycobacteria, Mycobacterium smegmatis, and the interaction of the homotetrameric SSBs with uracil DNA glycosylases (UDGs) from M. smegmatis (Msm), Mycobacterium tuberculosis (Mtu) and Escherichia coli (Eco). UDG is a crucial DNA repair enzyme, which removes the promutagenic uracil residues. MsmSSB stimulates activity of the homologous Msm UDG and of the heterologous Mtu-, and Eco-UDGs. On the contrary, while the MtuSSB stimulates the Mtu UDG, it inhibits the other two UDGs. Although the MsmSSB shares 84% identity with MtuSSB, the two are strikingly different, in that MsmSSB contains a glycine-rich segment (11 out of 13 residues) in the spacer connecting the N-terminal DNA-binding domain with the C-terminal acidic tail. While the DNA-binding properties of MsmSSB, such as its affinity to oligomeric DNA, requirement of minimum size DNA and the modes of interaction are indistinguishable from those of Eco-, and Mtu-SSBs, it is unclear if the glycine-rich segment confers structural advantage to MsmSSB, responsible for its stimulatory effect on all UDGs tested. More importantly, by using a small polypeptide inhibitor of UDGs, and the deletion mutants of SSBs, we suggest that the C-terminal acidic tail of the SSBs interacts within the DNA-binding groove of the UDGs, and propose a role for SSBs in the recruitment of UDGs to the damaged DNA.

Global genome repair of 8-oxoG in hamster cells requires a functional CSB gene product

Cockayne syndrome (CS) is an autosomal recessive human disease characterized by UV-sensitivity as well as neurological and developmental abnormalities. Two complementation groups have been established, designated CS-A and CS-B. Traditionally, CSA and CSB have been ascribed a function in the transcription-coupled repair (TCR) pathway of nucleotide excision repair (NER) that efficiently removes bulky lesions from the transcribed strand of RNA polymerase II transcribed genes. To assess the role of the CSB protein in the repair of the highly mutagenic base lesion 7,8-dihydro-8-oxoguanine (8-oxoG), we have investigated the removal of this lesion using an in vitro incision approach with cell extracts as well as an in vivo approach with a modified protocol of the gene-specific repair assay, which allows the measurement of base lesion repair in intragenomic sequences. Our results demonstrate that the integrity of the CSB protein is pivotal for processes leading to incision at the site of 8-oxoG and that the global genome repair (GGR) of this lesion requires a functional CSB gene product in vivo.

A quantitative model of human DNA base excision repair. I. Mechanistic insights

Base excision repair (BER) is a multistep process involving the sequential activity of several proteins that cope with spontaneous and environmentally induced mutagenic and cytotoxic DNA damage. Quantitative kinetic data on single proteins of BER have been used here to develop a mathematical model of the BER pathway. This model was then employed to evaluate mechanistic issues and to determine the sensitivity of pathway throughput to altered enzyme kinetics. Notably, the model predicts considerably less pathway throughput than observed in experimental in vitro assays. This finding, in combination with the effects of pathway cooperativity on model throughput, supports the hypothesis of cooperation during abasic site repair and between the apurinic/apyrimidinic (AP) endonuclease, Ape1, and the 8-oxoguanine DNA glycosylase, Ogg1. The quantitative model also predicts that for 8-oxoguanine and hydrolytic AP site damage, short-patch Polbeta-mediated BER dominates, with minimal switching to the long-patch subpathway. Sensitivity analysis of the model indicates that the Polbeta-catalyzed reactions have the most control over pathway throughput, although other BER reactions contribute to pathway efficiency as well. The studies within represent a first step in a developing effort to create a predictive model for BER cellular capacity.

Structural basis for poor uracil excision from hairpin DNA. An NMR study

Two-dimensional NMR and molecular dynamics simulations have been used to determine the three-dimensional structures of two hairpin DNA structures: d-CTAGAG GATCCUTTTGGATCCT (abbreviated as U1-hairpin) and d-CTAGAGGATCCTTUTGGATCCT (abbreviated as U3-hairpin). The 1H resonances of both of these hairpin structures have been assigned almost completely. NMR restrained molecular dynamics and energy minimization procedures have been used to describe the three-dimensional structures of these hairpins. This study and concurrent NMR structural studies on two other d-CTAGAGGA TCCTUTTGGATCCT (abbreviated as U2-hairpin) and d-CTAGAGGATCCTTTUGGATCCT (abbreviated as U4-hairpin) have shed light upon various interactions reported between Echerichia coli uracil DNA glycosylase (UDG) and uracil-containing DNA. The backbone torsion angles, which partially influence the local conformation of U12 and U14 in U1 and U3-hairpins, respectively, are probably locked in the trans conformation as in the case of U13 in the U2-hairpin. Such a stretched-out backbone conformation in the vicinity of U12 and U14 is thought to be the reason why the Km value is poor for U1- and U3-hairpins as it is for the U2-hairpin. Furthermore, the bases U12 and U14 in both U1- and U3-hairpins adopt an anti conformation, in contrast with the base conformation of U13 in the U2-hairpin, which adopts a syn conformation. The clear discrepancy observed in the U-base orientation with respect to the sugar moieties could explain why the Vmax value is 10- to 20-fold higher for the U1- and U3-hairpins compared with the U2-hairpin. Taken together, these observations support our interpretation that the unfavourable backbone results in a poor Km value, whereas the unfavourable nucleotide conformation results in a poor Vmax value. These two parameters therefore make the U1- and U3-hairpins better substrates for UDG compared with the U2-hairpin, as reported earlier [Kumar, N. V. & Varshney, U. (1997) Nucleic Acids Res. 25, 2336-2343.].

UV-induced DNA damage and repair: a review

Increases in ultraviolet radiation at the Earth's surface due to the depletion of the stratospheric ozone layer have recently fuelled interest in the mechanisms of various effects it might have on organisms. DNA is certainly one of the key targets for UV-induced damage in a variety of organisms ranging from bacteria to humans. UV radiation induces two of the most abundant mutagenic and cytotoxic DNA lesions such as cyclobutane-pyrimidine dimers (CPDs) and 6-4 photoproducts (6-4PPs) and their Dewar valence Isomers. However, cells have developed a number of repair or tolerance mechanism to counteract the DNA damage caused by UV or any other stressors. Photoreactivation with the help of the enzyme photolyase is one of the most important and frequently occurring repair mechanisms in a variety of organisms. Excision repair, which can be distinguished into base excision repair (BER) and nucleotide excision repair (NER), also plays an important role in DNA repair in several organisms with the help of a number of glycosylases and polymerases, respectively. In addition, mechanisms such as mutagenic repair or dimer bypass, recombinational repair, cell-cycle checkpoints, apoptosis and certain alternative repair pathways are also operative in various organisms. This review deals with UV-induced DNA damage and the associated repair mechanisms as well as methods of detecting DNA damage and its future perspectives.

Rosemary-stimulated reduction of DNA strand breaks and FPG-sensitive sites in mammalian cells treated with H2O2 or visible light-excited Methylene Blue

In this study possible protective effects of rosemary against oxidative DNA damage induced by H2O2- and visible light-excited Methylene Blue in colon cancer cells CaCo-2 and hamster lung cells V79 were investigated. The level of DNA damage (DNA strand breaks) was measured using the classical and modified single cell gel electrophoresis, so-called comet assay. Our findings showed that an ethanol extract from rosemary reduced the genotoxic activity of both agents after a long-term (24 h; 0.3 microg/ml) or short-term (2 h; 30 microg/ml) pre-incubation of cells. We suggest that the extract of rosemary exhibits a protective effect against oxidative damage to DNA as a consequence of scavenging of both *OH radicals and singlet oxygen ((1)O2).

Influence of nitric oxide on the generation and repair of oxidative DNA damage in mammalian cells

We have analysed the effects of endogenously and exogenously generated nitric oxide (NO) in cultured mammalian fibroblasts on: (i) the steady-state (background) levels of oxidative DNA base modifications; (ii) the susceptibility of the cells to the induction of additional DNA damage and micronuclei by H(2)O(2); and (iii) the repair kinetics of various types of DNA modifications. Steady-state levels of oxidative DNA base modifications, measured by means of an alkaline elution assay in combination with the repair endonuclease Fpg protein, were similar in NO-overproducing B6 mouse fibroblasts stably transfected with an inducible NO synthase (iNOS) and in control cells. Increased oxidative damage was only observed after exposure to high (toxic) concentrations of exogenous NO generated by decomposition of dipropylenetriamine-NONOate (DPTA-NONOate). Under these conditions, the spectrum of DNA modifications was similar to that induced by 3-morpholinosydnonimine, which generates peroxynitrite. The repair rate of additional oxidative DNA base modifications induced by photosensitization was not affected by the endogenous NO generation in the iNOS-transfected cells. However, it was completely blocked after pre-treatment with DPTA-NONOate at concentrations that did not cause oxidative DNA damage by themselves. In contrast, the repair of DNA single-strand breaks, sites of base loss (AP sites) and UVB-induced pyrimidine photodimers, was not affected. The endogenous generation of NO in the iNOS-transfected fibroblasts was associated with a protection from DNA single-strand break formation and micronuclei induction by H(2)O(2). These results indicate that NO generates cellular DNA damage only inefficiently and can even protect from DNA damage by H(2)O(2), but it selectively inhibits the repair of oxidative DNA base modifications.

Free radicals-mediated induction of oxidized DNA bases and DNA-protein cross-links by nickel chloride

Using the comet assay, we showed that nickel chloride at 250-1000 microM induced DNA damage in human lymphocytes, measured as the change in comet tail moment, which increased with nickel concentration up to 500 microM and then decreased. Observed increase might follow from the induction of strand breaks or/and alkali-labile sites (ALS) by nickel, whereas decrease from its induction of DNA-DNA and/or DNA-protein cross-links. Proteinase K caused an increase in the tail moment, suggesting that nickel chloride at 1000 microM might cross-link DNA with nuclear proteins. Lymphocytes exposed to NiCl(2) and treated with enzymes recognizing oxidized and alkylated bases: endonuclease III (Endo III), formamidopyrimidine-DNA glycosylase (Fpg) and 3-methyladenine-DNA glycosylase II (AlkA), displayed greater extent of DNA damage than those not treated with these enzymes, indicating the induction of oxidized and alkylated bases by nickel. The incubation of lymphocytes with spin traps, 5,5-dimethyl-pyrroline N-oxide (DMPO) and PBN decreased the extent of DNA damage, which might follow from the production of free radicals by nickel. The pre-treatment with Vitamin C at 10 microM and Vitamin E at 25 microM decreased the tail moment of the cells exposed to NiCl(2) at the concentrations of the metal causing strand breaks or/and ALS. The results obtained suggest that free radicals may be involved in the formation of strand breaks or/and ALS in DNA as well as DNA-protein cross-links induced by NiCl(2). Nickel chloride can also alkylate DNA bases. Our results support thesis on multiple, free radicals-based genotoxicity pathways of nickel.

Long-range oxidative damage in duplex DNA: the effect of bulged G in a G-C tract and tandem G/A mispairs

Two series of duplex DNA oligomers were prepared having an anthraquinone derivative (AQ) covalently linked at a 5'-terminus. Irradiation of the AQ at 350 nm leads to injection of an electron hole (radical cation) into the DNA. The radical cation migrates through the DNA causing reaction primarily at G(n) sequences. In one series, GA tandem mispairs are inserted between GG steps to assess the effect of the mispair on the transport of the radical cation, reaction (damage) caused by the radical cation at the mispair, and repair of the resulting damage by formamidopyrimidine DNA glycosylase (Fpg). In the second series, a bulged guanine in a G3C2 sequence is interposed between the GG steps. These experiments reveal that neither G/A tandem mispairs nor bulged guanines are significant barriers to long-range charge migration in DNA. The radical cation does not cause reaction at guanines in the G/A tandem mispair. Reaction does occur at the bulged guanine, but it is repaired by Fpg.

Mechanism underlying replication protein a stimulation of DNA ligase I

Replication protein A (RPA) is a heterotrimeric single-stranded DNA-binding protein that participates in multiple DNA transactions that include replication and repair. Base excision repair is a central DNA repair pathway, responsible for the removal of damaged bases. We have shown previously that RPA was able to stimulate long patch base excision repair reconstituted in vitro. Herein we show that human RPA stimulates the activity of the base excision repair component human DNA ligase I by approximately 15-fold. Other analyzed single-stranded binding proteins would not substitute, attesting to the specificity of the stimulation. Conversely, RPA was unable to stimulate the functionally homologous ATP-dependent ligase from T4 bacteriophage. Kinetic analyses suggest that catalysis of ligation is enhanced by RPA, as a 4-fold increase in k(cat) is observed, whereas K(m) is not significantly changed. Substrate competition experiments further support the conclusion that RPA does not alter the specificity or rate of substrate binding by DNA ligase I. Additionally, RPA is unable to significantly enhance ligation on substrates containing an unannealed 3'-upstream primer terminus, suggesting that RPA does not stabilize the nick site to enhance ligase recognition. Furthermore when DNA ligase I is pre-bound to the substrate and limited to a single turnover, RPA is still able to stimulate ligation. Overall, the results support a mechanism of stimulation that involves increasing the rate of catalysis of ligation.

Repair of 8-oxoguanine and Ogg1-incised apurinic sites in a CHO cell line

The repair mechanisms involved in the removal of 8-oxo-7,8-dihydroguanine (8-oxoG) in damaged DNA have been investigated using cell-free extracts or purified proteins. However, in vivo repair assays are required to further dissect mechanisms involved in the repair of 8-oxoG in the cellular context. In this study, we analyzed the removal of 8-oxoG from plasmids that contain a single 8-oxoG.C base pair in a sequence that can be transcribed (TS) or nontranscribed (NTS) in a chinese hamster ovary (CHO) cell line. The results show that 8-oxoG located in a TS is removed faster than in a NTS, indicating transcription-coupled repair (TCR) of 8-oxoG in rodent cells. The results also show that CHO cells efficiently repair DNA molecules that contain an Ogg1-incised AP site, which is the first intermediate in the course of base excision repair of 8-oxoG.

Properties and functions of human uracil-DNA glycosylase from the UNG gene

The human UNG-gene at position 12q24.1 encodes nuclear (UNG2) and mitochondrial (UNG1) forms of uracil-DNA glycosylase using differentially regulated promoters, PA and PB, and alternative splicing to produce two proteins with unique N-terminal sorting sequences. PCNA and RPA co-localize with UNG2 in replication foci and interact with N-terminal sequences in UNG2. Mitochondrial UNG1 is processed to shorter forms by mitochondrial processing peptidase (MPP) and an unidentified mitochondrial protease. The common core catalytic domain in UNG1 and UNG2 contains a conserved DNA binding groove and a tight-fitting uracil-binding pocket that binds uracil only when the uracil-containing nucleotide is flipped out. Certain single amino acid substitutions in the active site of the enzyme generate DNA glycosylases that remove either thymine or cytosine. These enzymes induce cytotoxic and mutagenic abasic (AP) sites in the E. coli chromosome and were used to examine biological consequences of AP sites. It has been assumed that a major role of the UNG gene product(s) is to repair mutagenic U:G mispairs caused by cytosine deamination. However, one major role of UNG2 is to remove misincorporated dUMP residues. Thus, knockout mice deficient in Ung activity (Ung-/- mice) have only small increases in GC-->AT transition mutations, but Ung-/- cells are deficient in removal of misincorporated dUMP and accumulate approximately 2000 uracil residues per cell. We propose that BER is important both in the prevention of cancer and for preserving the integrity of germ cell DNA during evolution.

Synthesis, stability, and conformation of the formamidopyrimidine G DNA lesion

The formamidopyrimidine (FapydGua) lesion, derived from the nucleobase guanine, is a major DNA lesion involved in mutagenesis and carcinogenesis. To date, the chemical information available about this main lesion is very limited. Herein, we describe a synthesis and a detailed characterization of the acetyl-protected monomer of the FapydGua lesion. Stability studies in DMSO and in water/acetonitrile show that the N-glycosidic bond, previously thought to be highly labile, is much more stable than anticipated. Decomposition of the FapydGua lesion proceeds with half-life times of 37.8 h for the beta-anomer and 65.2 h for the alpha-anomer in water/acetonitrile. The relaxation time for the anomerization reaction was determined to tau = 6.5 h at room temperature. Most important, it was found that the formamido group, which is critical for the lesion recognition process by repair enzymes, is fixed in the cis-conformation in apolar solvents such as chloroform. This conformation enables the formation of a hydrogen bond between the carbonyl oxygen of the formamide and the NH of the N-glycosidic bond within the framework of a seven-membered ring system. This has consequences for the recognition of the lesion by repair enzymes (hOGG1 and Fpg protein). These enzymes were so far believed to recognize the carbonyl group of the FapydGua lesion. Our investigations show that this carbonyl group is not readily accessible because it is almost buried in the dominating cis-conformation. In agreement with the recent X-ray structure of hOGG1 in complex with 8-oxo-7,8-dihydroguanine-containing DNA, we can conclude that repair enzymes can contact both lesions only via the N(7)-H group, which is a hydrogen-bond acceptor in guanine.

Homogeneous repair of nuclear genes after experimental stroke

The repair of oxidative DNA lesions (ODLs) in the nucleus of ischemic cortical brain cells was examined following experimentally induced stroke by occluding the right middle cerebral artery and both common carotid arteries for 60-90 min followed by reperfusion in male long-Evans hooded rats. The control group consisted of sham-operated animals undergoing the same surgery without vessel occlusion. Using a gene-specific assay based upon the presence of Escherichia coli Fpg protein-sensitive sites, we noted that animals with stroke exhibited six and four ODLs per gene in the actin and DNA polymerase-beta genes, respectively. This was increased from one per four copies of each gene in the sham-operated control (p < 0.01). One half of the initial ODLs was repaired within 30 min, and 83% of them were repaired as early as 45 min of reperfusion. There was no further increase when gene repair was measured again at 2 h of reperfusion. The rates of active repair within 45 min of reperfusion were the same in these two genes (p = 0.103, ANOVA). BrdU (10 mg/kg) was administered via intraperitoneal injection at least one day before surgery. We observed that there was no significant incorporation of BrdU triphosphates into genomic DNA during active repair, but there were significant amounts of BrdU triphosphate in nuclear DNA after active repair. The result indicates that genomic repair of ODLs in the brain did not significantly incorporate BrdU, and the initiation of neurogenesis probably starts after the completion of repair in the brain.