Formation of 2'-deoxyoxanosine from 2'-deoxyguanosine and nitrous acid: mechanism and intermediates

Formation Mechanism of Inter-Crosslink in DNA by Nitrogen Oxides Pollutants through A Diazonium Intermediate

Outdoor air pollution is a mixture of multiple atmospheric pollutants, among which nitrogen oxide (NOx) stands out due to its association with several diseases. NOx reactivity can conduct to DNA damage as severe as interstrand crosslinks (ICL) formation, that in turn is able to block DNA replication and transcription. Experimental studies have suggested that the ICL formation due to NOx is realized through a diazonium intermediate (DI). In this work, we have modeled the DI structure, including a DNA double-strand composed of two base pairs GC/CG, being diazotized as one of the guanine nucleotides. The structural stability of DNA with DI lesion was essayed through 500 ns molecular dynamics simulations. It was found that the DNA structure of the oligonucleotide is stable when the DI is present since the loss of a Guanine–Cytosine hydrogen bond is replaced by the presence of two cation-π interactions. Additionally, we have studied the mechanism of formation of a crosslink between the two guanine nucleobases from the modeled DI by carrying out DFT calculations at the M06-L/DNP+ level of theory. Our results show that the mechanism is thermodynamically favored by a strong stabilization of the ICL product, and the process is kinetically viable since its limiting stage is accessible.

Nucleobase-involved native chemical ligation: a novel reaction between an oxanine nucleobase and N-terminal cysteine for oligonucleotide-peptide conjugation

In bioconjugation chemistry, achieving a target-specific reaction for a non-modified amino acid is challenging. Here, we report a novel nucleobase-involved native chemical ligation (NbCL) that allows a site-specific oligonucleotide-peptide conjugation via a new S-N acyl transfer reaction between an oxanine nucleobase and N-terminal cysteine.

Oxanosine Monophosphate Is a Covalent Inhibitor of Inosine 5'-Monophosphate Dehydrogenase

Reactive nitrogen species (RNS) are produced during infection and inflammation, and the effects of these agents on proteins, DNA, and lipids are well recognized. In contrast, the effects of RNS damaged metabolites are less appreciated. 5-Amino-3-β-(d-ribofuranosyl)-3 H-imidazo-[4,5- d][1,3]oxazine-7-one (oxanosine) and its nucleotides are products of guanosine nitrosation. Here we demonstrate that oxanosine monophosphate (OxMP) is a potent reversible competitive inhibitor of IMPDH. The value of K_i varies from 50 to 340 nM among IMPDHs from five different organisms. UV spectroscopy and X-ray crystallography indicate that OxMP forms a ring-opened covalent adduct with the active site Cys (E-OxMP*). Unlike the covalent intermediate of the normal catalytic reaction, E-OxMP* does not hydrolyze, but instead recyclizes to OxMP. IMPDH inhibitors block proliferation and can induce apoptosis, so the inhibition of IMPDH by OxMP presents another potential mechanism for RNS toxicity.

Nitrosative deamination of 2'-deoxyguanosine and DNA by nitrite, and antinitrosating activity of β-carboline alkaloids and antioxidants

Endogenous and dietary nitrite produces reactive nitrogen species (RNS) that react with DNA causing mutations. The nitrosation of 2'-deoxyguanosine (dGuo) and DNA with nitrite was studied under different conditions, and the reaction and degradation products identified and analysed by HPLC-DAD-MS. Nitrosative deamination of dGuo produced xanthine along with 2'-deoxyxanthosine whereas DNA afforded xanthine. Formation of xanthine increased with nitrite concentration and in low pH such as that of stomach. Xanthine was measured as a marker of nitrosation of dGuo and DNA, and it was subsequently used to study the antinitrosating activity of β-carboline alkaloids, and selected antioxidants. Food-occurring tetrahydro-β-carbolines (THβCs) decreased nitrosative deamination of dGuo and DNA under conditions simulating the stomach. Antinitrosating activity was also evidenced for flavonoids (catechin, quercetin) and indole (melatonin) antioxidants. Among THβCs the most active antinitrosating compounds were 1,2,3,4-tetrahydro-β-carboline-3-carboxylic acids (THβC-3-COOHs) that reacted with nitrite to give N-nitroso derivatives as main products along with 3,4-dihydro-β-carboline-3-carboxylic acids and aromatic β-carbolines (norharman and harman). Antinitrosating activity of THβCs correlated well with the formation of N-nitroso-THβC-3-COOHs. These N-nitroso derivatives were stable at pH 7 but degraded in acid conditions affording nitrosating species.

Inverting the G-Tetrad Polarity of a G-Quadruplex by Using Xanthine and 8-Oxoguanine

G-quadruplexes are four-stranded nucleic acid structures that are built from consecutively stacked guanine tetrad (G-tetrad) assemblies. The simultaneous incorporation of two guanine base lesions, xanthine (X) and 8-oxoguanine (O), within a single G-tetrad of a G-quadruplex was recently shown to lead to the formation of a stable G⋅G⋅X⋅O tetrad. Herein, a judicious introduction of X and O into a human telomeric G-quadruplex-forming sequence is shown to reverse the hydrogen-bond polarity of the modified G-tetrad while preserving the original folding topology. The control exerted over G-tetrad polarity by joint X⋅O modification will be valuable for the design and programming of G-quadruplex structures and their properties.

Xanthine and 8-oxoguanine in G-quadruplexes: formation of a G·G·X·O tetrad

G-quadruplexes are four-stranded structures built from stacked G-tetrads (G·G·G·G), which are planar cyclical assemblies of four guanine bases interacting through Hoogsteen hydrogen bonds. A G-quadruplex containing a single guanine analog substitution, such as 8-oxoguanine (O) or xanthine (X), would suffer from a loss of a Hoogsteen hydrogen bond within a G-tetrad and/or potential steric hindrance. We show that a proper arrangement of O and X bases can reestablish the hydrogen-bond pattern within a G·G·X·O tetrad. Rational incorporation of G·G·X·O tetrads in a (3+1) G-quadruplex demonstrated a similar folding topology and thermal stability to that of the unmodified G-quadruplex. pH titration conducted on X·O-modified G-quadruplexes indicated a protonation-deprotonation equilibrium of X with a pKa ∼6.7. The solution structure of a G-quadruplex containing a G·G·X·O tetrad was determined, displaying the same folding topology in both the protonated and deprotonated states. A G-quadruplex containing a deprotonated X·O pair was shown to exhibit a more electronegative groove compared to that of the unmodified one. These differences are likely to manifest in the electronic properties of G-quadruplexes and may have important implications for drug targeting and DNA-protein interactions.

Characterization of the deoxyguanosine-lysine cross-link of methylglyoxal

Methylglyoxal is a mutagenic bis-electrophile that is produced endogenously from carbohydrate precursors. Methylglyoxal has been reported to induce DNA-protein cross-links (DPCs) in vitro and in cultured cells. Previous work suggests that these cross-links are formed between guanine and either lysine or cysteine side chains. However, the chemical nature of the methylglyoxal induced DPC have not been determined. We have examined the reaction of methylglyoxal, deoxyguanosine (dGuo), and Nα-acetyllysine (AcLys) and determined the structure of the cross-link to be the N2-ethyl-1-carboxamide with the lysine side chain amino group (1). The cross-link was identified by mass spectrometry and the structure confirmed by comparison to a synthetic sample. Further, the cross-link between methylglyoxal, dGuo, and a peptide (AcAVAGKAGAR) was also characterized. The mechanism of cross-link formation is likely to involve an Amadori rearrangement.

Modification of DNA damage mechanisms by nitric oxide during ionizing radiation

Nitric oxide ((•)NO) is a very effective radiosensitizer of hypoxic mammalian cells. In vivo (•)NO may have effects on tumor vasculature and hence on tumor oxygenation and it may also interact with radiation-produced radicals to modify DNA lesions. Few studies have addressed this last aspect, and we report here specific base modifications that result from reaction of (•)NO with radicals in DNA bases and in plasmid DNA after irradiation. 2'-Deoxyxanthosine monophosphate and 2'-deoxy-8-azaguanosine monophosphate (8azadGMP) are formed upon γ-irradiation of 2'-deoxyguanosine monophosphate (dGMP) in the presence of micromolar levels of (•)NO in anoxia. In addition, the presence of (•)NO at physiological pH inhibits the formation of the well-described (•)OH-induced oxidation product of dGMP, 8-oxo-2'-deoxyguanosine monophosphate. Single-strand breaks are induced in plasmid DNA when γ-irradiated in anoxia, whereas in the presence of (•)NO the number of breaks is reduced by approximately threefold, and evidence is shown for the formation of 8azadGMP in these plasmids. The consequence of the base modifications by (•)NO are as yet unknown although additional breaks are revealed in irradiated plasmid DNA after treatment with glycosylases involved in base excision repair. V79-4 cells irradiated in anoxia show an enhancement in the number of γH2AX foci when (•)NO is present, particularly evident a few hours postirradiation, indicative of the formation of replication-induced DNA damage. We propose that the consequence of (•)NO-induced base modifications in anoxia contributes to its radiosensitization of cells.

Polyvinyl pyrrolidone promotes DNA cleavage by a ROS-independent and depurination mechanism

Polyvinyl pyrrolidone polymer (PVP) has been widely applied in biological and medical fields. A few in vitro studies indicated that PVP might cause toxicity. However, the underlying mechanism is poorly understood. In this work, we found that PVP directly induced strand breakages of various DNA molecules, implicating a cleavage activity. Moreover, reactive oxygen species (ROS) scavenging analysis shows that DNA cleavage activity of PVP is not related to ROS-induced oxidation. As revealed by gel electrophoresis and liquid chromatography/mass spectrometry analysis, the major cleavage products of DNA were identified as two purine bases, guanine and adenine, suggesting that PVPs have a novel depurination activity. The selective depurination and DNA cleavage activity of PVPs were further confirmed by studying the interaction of PVP with four nucleosides and four well-designed oligodeoxynucleotides probes containing specific nucleotides. This study may provide insights into PVP-DNA interactions and resultant genotoxicity and may also open a new way for DNA study.

Solution structure and stability of the DNA undecamer duplexes containing oxanine mismatch

Solution structures of DNA duplexes containing oxanine (Oxa, O) opposite a cytosine (O:C duplex) and opposite a thymine (O:T duplex) have been solved by the combined use of ¹H NMR and restrained molecular dynamics calculation. One mismatch pair was introduced into the center of the 11-mer duplex of [d(GTGACO₆CACTG)/d(CAGTGX₁₇GTCAC), X = C or T]. ¹H NMR chemical shifts and nuclear Overhauser enhancement (NOE) intensities indicate that both the duplexes adopt an overall right-handed B-type conformation. Exchangeable resonances of C₁₇ 4-amino proton of the O:C duplex and of T₁₇ imino proton of O:T duplex showed unusual chemical shifts, and disappeared with temperature increasing up to 30°C, although the melting temperatures were >50°C. The O:C mismatch takes a wobble geometry with positive shear parameter where the Oxa ring shifted toward the major groove and the paired C₁₇ toward the minor groove, while, in the O:T mismatch pair with the negative shear, the Oxa ring slightly shifted toward the minor groove and the paired T₁₇ toward the major groove. The Oxa mismatch pairs can be wobbled largely because of no hydrogen bond to the O1 position of the Oxa base, and may occupy positions in the strands that optimize the stacking with adjacent bases.

Synthesis of 2'-deoxyoxanosine from 2'-deoxyguanosine, conversion to its phosphoramidite, and incorporation into oxanine-containing oligodeoxynucleotides

Oxanine (Oxa, O) is one of the damaged bases produced from guanine (G) through nitrosative deamination induced by nitric oxide (NO) or nitrous acid (HNO(2)). Large-scale preparation of Oxa-containing oligodeoxynucleotide (Oxa-ODN) with the desired base sequence is a prerequisite for exploring detailed properties of Oxa in DNA. This can be accomplished by incubation of G nucleosides with NaNO(2) in acetic acid buffer (pH 3.5) to produce Oxa nucleosides (e.g., 2'-deoxyoxanosine or dOxo), conversion of dOxo to DMT-dOxo-amidite by tritylation and conventional phosphoramidation, and subsequent synthesis of Oxa-ODN. The presence of Oxa in the synthetic ODN is confirmed by enzymatic digestion. Oxa-ODN is useful for analyzing the biochemical and biophysical properties of Oxa in DNA, which is believed to be involved in NO-induced genotoxicity and cytotoxicity. In addition, since Oxa possesses the carbodiimide-activated carboxylate function (O-acylisourea structure), Oxa-ODN can be used as a functional DNA oligomer that makes covalent cross-linkages with amine or amine-containing biomolecules and amine-modified solid surfaces.

Modeling the dissociative hydrolysis of the natural DNA nucleosides

Two-dimensional PCM-B3LYP/6-31+G(d) potential energy surfaces for the hydrolysis of the four natural 2'-deoxyribonucleosides (2'-deoxyadenosine, 2'-deoxyguanosine, 2'-deoxycytidine, and thymidine) are characterized using a model that includes both implicit (bulk) solvent effects and (three or four) explicit water molecules in the optimization routine. For the first time, the experimentally predicted dissociative (S(N)1) mechanism is found to be favored over the synchronous (S(N)2) pathway for all nucleosides studied. Due to the success of our model in stabilizing the charge-separated intermediates along the S(N)1 pathway, it is proposed that the new model presented here is the smallest system capable of generating the experimentally predicted oxacarbenium cation intermediate. We therefore stress that dissociative mechanisms should be studied with methodologies that account for the (bulk) environment in the optimization routine, where these effects are often only included as a correction to the energy in the current literature. In addition to accounting for charge stabilization through implicit solvation, nucleophile activation and leaving group stabilization should also be explicitly introduced into the model to further stabilize the system. Our work also emphasizes the importance of studying the Gibbs surface, which in some cases provides a better description of chemically important regions of the reaction surface or changes the calculated trend in the magnitude of dissociative barriers. In addition, it is proposed that the methodology presented in this study can be used to calculate uncatalyzed deglycosylation barriers for a range of DNA nucleosides, which when compared to the corresponding enzyme-catalyzed reactions, will allow the prediction of the rate enhancement (barrier reduction) due to the enzyme.

Steric and electrostatic effects at the C2 atom substituent influence replication and miscoding of the DNA deamination product deoxyxanthosine and analogs by DNA polymerases

Deoxyinosine (dI) and deoxyxanthosine (dX) are both formed in DNA at appreciable levels in vivo by deamination of deoxyadenosine (dA) and deoxyguanosine (dG), respectively, and can miscode. Structure-activity relationships for dA pairing have been examined extensively using analogs but relatively few studies have probed the roles of the individual hydrogen-bonding atoms of dG in DNA replication. The replicative bacteriophage T7 DNA polymerase/exonuclease and the translesion DNA polymerase Sulfolobus solfataricus pol IV were used as models to discern the mechanisms of miscoding by DNA polymerases. Removal of the 2-amino group from the template dG (i.e., dI) had little impact on the catalytic efficiency of either polymerase, as judged by either steady-state or pre-steady-state kinetic analysis, although the misincorporation frequency was increased by an order of magnitude. dX was highly miscoding with both polymerases, and incorporation of several bases was observed. The addition of an electronegative fluorine atom at the 2-position of dI lowered the oligonucleotide T(m) and strongly inhibited incorporation of dCTP. The addition of bromine or oxygen (dX) at C2 lowered the T(m) further, strongly inhibited both polymerases, and increased the frequency of misincorporation. Linear activity models show the effects of oxygen (dX) and the halogens at C2 on both DNA polymerases as mainly due to a combination of both steric and electrostatic factors, producing a clash with the paired cytosine O2 atom, as opposed to either bulk or perturbation of purine ring electron density alone.

Acetylation of the amino group on guanosine induced by nitric oxide in acetonitrile under aerobic conditions

When nitric oxide was bubbled into acetonitrile under aerobic conditions, the solution showed a cobalt-blue color. Addition of guanosine into the solution generated N2-acetylguanosine as a major product. The result of the reaction using 15N labeled acetonitrile indicated that the nitrogen atom of the acetylated exocyclic amino group on N2-acetylguanosine originated from acetonitrile. We discuss the reaction mechanism for the acylation.

Repair of deaminated base damage by Schizosaccharomyces pombe thymine DNA glycosylase

Thymine DNA glycosylases (TDG) in eukaryotic organisms are known for their double-stranded glycosylase activity on guanine/uracil (G/U) base pairs. Schizosaccharomyces pombe (Spo) TDG is a member of the MUG/TDG family that belongs to a uracil DNA glycosylase superfamily. This work investigates the DNA repair activity of Spo TDG on all four deaminated bases: xanthine (X) and oxanine (O) from guanine, hypoxanthine (I) from adenine, and uracil from cytosine. Unexpectedly, Spo TDG exhibits glycosylase activity on all deaminated bases in both double-stranded and single-stranded DNA in the descending order of X>I>U>>O. In comparison, human TDG only excises deaminated bases from G/U and, to a much lower extent, A/U and G/I base pairs. Amino acid substitutions in motifs 1 and 2 of Spo TDG show a significant impact on deaminated base repair activity. The overall mutational effects are characterized by a loss of glycosylase activity on oxanine in all five mutants. L157I in motif 1 and G288M in motif 2 retain xanthine DNA glycosylase (XDG) activity but reduce excision of hypoxanthine and uracil, in particular in C/I, single-stranded hypoxanthine (ss-I), A/U, and single-stranded uracil (ss-U). A proline substitution at I289 in motif 2 causes a significant reduction in XDG activity and a loss of activity on C/I, ss-I, A/U, C/U, G/U, and ss-U. S291G only retains reduced activity on T/I and G/I base pairs. S163A can still excise hypoxanthine and uracil in mismatched base pairs but loses XDG activity, making it the closest mutant, functionally, to human TDG. The relationship among amino acid substitutions, binding affinity and base recognition is discussed.

Investigation of DNA-protein cross-link formation between lysozyme and oxanine by mass spectrometry

Reactive nitrogen species are implicated in inflammatory diseases and cancers. Oxanine (Oxa) is a DNA lesion product originating from the guanine base through exposure to nitric oxide, nitrous acid, or N-nitrosoindoles. Oxanine was found to mediate formation of DNA-protein cross-links (DPCs) in the cell extract. We have previously characterized two DNA-protein cross-links from the reaction between Oxa and glutathione: namely, the thioester and the amide. In this study, lysozyme was used to study site-specific modification on protein by Oxa moieties in DNA. With the aid of nanoLC coupled with nanospray ionization tandem mass spectrometry, addition of Oxa was found at Lys13, Lys97, Lys116, Ser85, and Ser86 of lysozyme when it was treated with 2'-deoxyoxanosine (dOxo). Furthermore, incubation of lysozyme with Oxa-containing calf thymus DNA, produced by treating DNA with nitrous acid, led to lysozyme modification at Lys116, Ser85, and Ser86. Interestingly, none of the cysteine residues was modified by dOxo, in contrast with our previous findings that dOxo reacted with oxidized glutathione disulfide, forming the thioester. This might be due to the half-life of the dOxo-derived thioester being 2.2 days at the pH of incubation. Furthermore, the sites of modifications on lysozyme are in good agreement with the solvent accessibility of the residues. Since repair of Oxa-derived DPCs has not been extensively investigated, these results suggest that these stable DPCs might represent important forms of cellular damage caused by reactive nitrogen species involved in inflammationrelated diseases.

Biophysical stability and enzymatic recognition of oxanine in DNA

Oxanine (Oxa), which is one of the major products generated from guanine by nitrosative oxidation and is as long-lived as Gua in DNA, has been thought to be one of the major causes for NO-induced DNA damage. In the present study, using several synthetic Oxa-containing oligodeoxynucleotides, biophysical stability and enzymatic recognition of Oxa was investigated in DNA strands. It was found that Oxa did not mediate marked distortion in the whole DNA structure although Oxa pairing with 4 normal bases decreased thermal stability of the DNA duplexes compared to Gua:Cyt base pair. Regarding the responses of the DNA-relevant enzymes to Oxa, it was determined that Oxa was recognized as Gua except that DNA polymerases incorporated Thy as well as Cyt opposite Oxa. These results imply that Oxa tends to behave as a kind of naturally occurring base, Gua and therefore, would be involved in the genotoxic and cytotoxic threats of NO in cellular system.

Cytotoxicity and mutagenicity of endogenous DNA base lesions as potential cause of human aging

Endogenous factors constitute a substantial source of damage to the genomic DNA. The type of damage includes a number of different base lesions and single- and double-strand breaks. Unrepaired DNA damage can give rise to mutations and may cause cell death. A number of studies have demonstrated an association between aging and the accumulation of DNA damage. This may be attributed to reduced DNA repair with age, although this is apparently not a general feature for all types of damage and repair mechanisms. Therefore, detailed studies that improve our knowledge of DNA repair systems as well as mutagenic and toxic effects of DNA lesions will help us to gain a better insight into the mechanisms of aging. The aim of this review is to provide a brief description of cytotoxic and mutagenic endogenous DNA lesions that are mainly repaired by base excision repair and single-strand break repair pathways and to discuss the potential role of DNA lesions and DNA repair dysfunction in the onset of human aging.

Ammonia elimination from protonated nucleobases and related synthetic substrates

The results are reported of mass-spectrometric studies of the nucleobases adenine 1h (1, R = H), guanine 2h, and cytosine 3h. The protonated nucleobases are generated by electrospray ionization of adenosine 1r (1, R = ribose), guanosine 2r, and deoxycytidine 3d (3, R = deoxyribose) and their fragmentations were studied with tandem mass spectrometry. In contrast to previous EI-MS studies of the nucleobases, NH(3) elimination does present a major path for the fragmentations of the ions [1h + H](+), [2h + H](+), and [3h + H](+). The ion [2h + H - NH(3)](+) also was generated from the acyclic precursor 5-cyanoamino-4-oxomethylene-dihydroimidazole 13h and from the thioether derivative 14h of 2h (NH(2) replaced by MeS). The analyses of the modes of initial fragmentation is supported by density functional theoretical studies. Conjugate acids 15-55 were studied to determine site preferences for the protonations of 1h, 2h, 3h, 13h, and 14h. The proton affinity of the amino group hardly ever is the substrate's best protonation site, and possible mechanisms for NH(3) elimination are discussed in which the amino group serves as the dissociative protonation site. The results provide semi-direct experimental evidence for the existence of the pyrimidine ring-opened cations that we had proposed on the basis of theoretical studies as intermediates in nitrosative nucleobase deamination.

Oxanine DNA glycosylase activities in mammalian systems

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

Direct immobilization of DNA oligomers onto the amine-functionalized glass surface for DNA microarray fabrication through the activation-free reaction of oxanine

Oxanine having an O-acylisourea structure was explored to see if its reactivity with amino group is useful in DNA microarray fabrication. By the chemical synthesis, a nucleotide unit of oxanine (Oxa-N) was incorporated into the 5′-end of probe DNA with or without the -(CH₂)_n- spacers (n = 3 and 12) and found to immobilize the probe DNA covalently onto the NH₂-functionalized glass slide by one-pot reaction, producing the high efficiency of the target hybridization. The methylene spacer, particularly the longer one, generated higher efficiency of the target recognition although there was little effect on the amount of the immobilized DNA oligomers. The post-spotting treatment was also carried out under the mild conditions (at 25 or 42°C) and the efficiencies of the immobilization and the target recognition were evaluated similarly, and analogous trends were obtained. It has also been determined under the mild conditions that the humidity and time of the post-spotting treatment, pH of the spotting solution and the synergistic effects with UV-irradiation largely contribute to the desired immobilization and resulting target recognition. Immobilization of DNA oligomer by use of Oxa-N on the NH₂-functionalized surface without any activation step would be employed as one of the advanced methods for generating DNA-conjugated solid surface.

NO-dependent modifications of nucleic acids

This review is devoted to chemical transformations of nucleic acids and their components under the action of nitrogen oxide metabolites. The deamination reaction of bases is discussed in the context of possible competing transformations of its intermediates (nitrosamines, diazonium cations, diazotates, triazenes, and diazoanhydrides) and mechanisms of crosslink formation with proteins and nucleic acids. The oxidation and nitration of bases by NO2 is considered together with the possibility of radical transfer to domains from the base stacks in DNA. Reduction of redox potentials of bases as a result of stacking interactions explains the possibility of their reactions within nucleic acids with the oxidants whose redox potential is insufficient for the effective reactions with mononucleotides. Modifications of nucleic acids with peroxynitrite derivatives are discussed in the context of the effect of the DNA primary structure and the modification products formed on the reactivity of single bases. The possibility of reduction of nitro groups within modified bases to amino derivatives and their subsequent diazotation is considered. The substitution of oxoguanine for nitroguanine residues may result; the reductive diazotation can lead to undamaged guanine. The intermediate modified bases, e.g., 8-aminoguanine and 8-diazoguanine, were shown to participate in noncanonical base pairing, including the formation of more stable bonds with two bases, which is characteristic of the DNA Z-form. A higher sensitivity of RNA in comparison with DNA to NO-dependent modifications (NODMs) is predicted on the basis of the contribution of medium microheterogeneity and the known mechanisms of nitrosylation and nitration. The possible biological consequences of nucleic acids NODMs are briefly considered. It is shown that the NODMs under the action of nitrogen oxide metabolites generated by macrophages and similar cells in inflammations or infections should lead to a sharp increase in the number of mutations in the case of RNA-containing viruses. As a result, the defense mechanisms of the host organism may contribute to the appearance of new, including more dangerous, variants of infecting viruses.

Evidence for mutagenesis by nitric oxide during nitrate metabolism in Escherichia coli

In Escherichia coli, nitrosative mutagenesis may occur during nitrate or nitrite respiration. The endogenous nitrosating agent N2O3 (dinitrogen trioxide, nitrous anhydride) may be formed either by the condensation of nitrous acid or by the autooxidation of nitric oxide, both of which are metabolic by-products. The purpose of this study was to determine which of these two agents is more responsible for endogenous nitrosative mutagenesis. An nfi (endonuclease V) mutant was grown anaerobically with nitrate or nitrite, conditions under which it has a high frequency of A:T-to-G:C transition mutations because of a defect in the repair of hypoxanthine (nitrosatively deaminated adenine) in DNA. These mutations could be greatly reduced by two means: (i) introduction of an nirB mutation, which affects the inducible cytoplasmic nitrite reductase, the major source of nitric oxide during nitrate or nitrite metabolism, or (ii) flushing the anaerobic culture with argon (which should purge it of nitric oxide) before it was exposed to air. The results suggest that nitrosative mutagenesis occurs during a shift from nitrate/nitrite-dependent respiration under hypoxic conditions to aerobic respiration, when accumulated nitric oxide reacts with oxygen to form endogenous nitrosating agents such as N2O3. In contrast, mutagenesis of nongrowing cells by nitrous acid was unaffected by an nirB mutation, suggesting that this mutagenesis is mediated by N2O3 that is formed directly by the condensation of nitrous acid.

Relatively small increases in the steady-state levels of nucleobase deamination products in DNA from human TK6 cells exposed to toxic levels of nitric oxide

Nitric oxide (NO) is a physiologically important molecule that has been implicated in the pathophysiology of diseases associated with chronic inflammation, such as cancer. While the complicated chemistry of NO-mediated genotoxicity has been extensively study in vitro, neither the spectrum of DNA lesions nor their consequences in vivo have been rigorously defined. We have approached this problem by exposing human TK6 lymphoblastoid cells to controlled steady-state concentrations of 1.75 or 0.65 microM NO along with 186 microM O2 in a recently developed reactor that avoids the anomalous gas-phase chemistry of NO and approximates the conditions at sites of inflammation in tissues. The resulting spectrum of nucleobase deamination products was defined using a recently developed liquid chromatography/mass spectrometry (LC/MS) method, and the results were correlated with cytotoxicity and apoptosis. A series of control experiments revealed the necessity of using dC and dA deaminase inhibitors to avoid adventitious formation of 2'-deoxyuridine (dU) and 2'-deoxyinosine (dI), respectively, during DNA isolation and processing. Exposure of TK6 cells to 1.75 microM NO and 186 microM O2 for 12 h (1260 microM x min dose) resulted in 32% loss of cell viability measured immediately after exposure and 87% cytotoxicity after a 24 h recovery period. The same exposure resulted in 3.5-, 3.8-, and 4.1-fold increases in dX, dI, and dU, respectively, to reach the following levels: dX, 7 (+/- 1) per 10(6) nt; dI, 25 (+/- 2.1) per 10(6) nt; and dU, 40 (+/- 3.8) per 10(6) nt. dO was not detected above the limit of detection of 6 lesions per 10(7) nt in 50 microg of DNA. A 12 h exposure to 0.65 microM NO and 190 microM O2 (468 microM x min dose) caused 1.7-, 1.8-, and 2.0-fold increases in dX, dI, and dU, respectively, accompanied by a approximately 15% (+/- 3.6) reduction in cell viability immediately after exposure. Again, dO was not detected. These results reveal modest increases in the steady-state levels of DNA deamination products in cells exposed to relatively cytotoxic levels of NO. This could result from limited nitrosative chemistry in nuclear DNA in cells exposed to NO or high levels of formation balanced by rapid repair of nucleobase deamination lesions in DNA.

Nitrative stress through formation of 8-nitroguanosine: insights into microbial pathogenesis

Reactive oxygen and nitrogen species, respectively, mediate oxidative and nitrative stresses by means of oxidation and nitration of various biomolecules including proteins, lipids, and nucleic acids. We have observed nitric oxide (NO)-dependent formation of 8-nitroguanosine and 3-nitrotyrosine during microbial infection, and we determined that both 8-nitroguanosine and 3-nitrotyrosine are useful biomarkers of nitrative stress. Of importance, however, is the great difference in biological characteristics of these two nitrated compounds. 8-Nitroguanosine has unique biochemical and pharmacological properties such as redox activity and mutagenic potential, which 3-nitrotyrosine does not. In this review, we discuss the mechanism of nitrative stress occurring during microbial infections, with special emphasis on biological functions of 8-nitroguanosine formed via NO during the host response to pathogens. These findings provide insights into NO-mediated pathogenesis not only of viral infections but also of many other diseases.

Chemical synthesis and thermodynamic characterization of oxanine-containing oligodeoxynucleotides

Oxanine (Oxa, O), one of the major damaged bases from guanine generated by NO- or HNO₂-induced nitrosative deamination, has been considered as a mutagen-potent lesion. For exploring more detailed properties of Oxa, large-scale preparation of Oxa-containing oligodeoxynucleotide (Oxa-ODN) with the desired base sequence is a prerequisite. In the present study, we have developed a chemical synthesis procedure of Oxa-ODNs and characterized thermodynamic properties of Oxa in DNA strands. First, 2′-deoxynucleoside of Oxa (dOxo) obtained from 2′-deoxyguanosine by HNO₂-nitrosation was subjected to 5′-O-selective tritylation to give 5′-O-(4,4′-dimethoxytrityl)-dOxo (DMT-dOxo) with a maximum yield of 70%. Subsequently, DMT-dOxo was treated with conventional phosphoramidation, which resulted in DMT-dOxo-amidite monomer with a maximum yield of 72.5%. The amidite obtained was used for synthesizing Oxa-ODNs: the coupling yields for Oxa incorporation were over 93%. The prepared Oxa-ODNs were employed for analyzing the thermodynamic properties of DNA duplexes containing base-matches of O:N [N; C (cytosine), T (thymine), G (guanine) or A (adenine)]. Melting temperatures (T_m) and thermodynamic stability (ΔG370) were found to be lower by 6.83∼13.41°C and 2.643∼6.047 kcal mol⁻¹, respectively, compared with those of oligodeoxynucleotides, which had the same base sequence except that O:N was replaced by G:C (wild type). It has also been found that Oxa-pairing with cytosine shows relatively high stability in DNA duplex compared with other base combinations. The orders of ΔΔG370 were O:C > O:T > O:A > O:G. The chemical synthesis procedure and thermodynamic characteristics of Oxa-ODNs established here will be helpful for elucidating the biological significance of Oxa in relation to genotoxic and repair mechanisms.

Cytosine catalysis of nitrosative guanine deamination and interstrand cross-link formation

Effects are discussed of the anisotropic DNA environment on nitrosative guanine deamination based on results of an ab initio study of the aggregate 3 formed by guaninediazonium ion 1 and cytosine 2. Within 3, the protonation of 2 by 1 is fast and exothermic and forms 6, an aggregate between betaine 4 (2-diazonium-9H-purin-6-olate) and cytosinium ion 5. Electronic structure analysis of 4 shows that this betaine is not mesoionic; only the negative charge is delocalized in the pi-system while the positive charge resides in the sigma-system. Potential energy surface exploration shows that both dediazoniation and ring-opening of betaine 4 in aggregate 6 are fast and exothermic and lead irreversibly to E-11, the aggregate between (E)-5-cyanoimino-4-oxomethylene-4,5-dihydroimidazole E-10 and 5. The computed pair binding energies for 3, 6, and E-11 greatly exceed the GC pair binding energy. While 1 can be a highly reactive intermediate in reactions of the "free nucleobase" (or its nucleoside and nucleotide), the cyanoimine 10 emerges as the key intermediate in nitrosative guanine deamination in ds-DNA and ds-oligonucleotides. In essence, the complementary nucleobase cytosine provides base catalysis and switches the sequence of deprotonation and dediazoniation. It is argued that this environment-induced switch causes entirely different reaction paths to products as compared to the respective "free nucleobase" chemistry, and the complete consistency is demonstrated of this mechanistic model with all known experimental results. Products might form directly from 10 by addition and ring closure, or their formation might involve water catalysis via 5-cyanoamino-4-imidazolecarboxylic acid 12 and/or 5-carbodiimidyl-4-imidazolecarboxylic acid 13. The pyrimidine ring-opened intermediates 10, 12, and 13 can account for the formations of xanthosine, the pH dependency and the environment dependency of oxanosine formation, the formation of the classical cross-link dG(N(2)())-to-dG(C2), including the known sequence specificity of its formation, and the formation of the structure-isomeric cross-link dG(N1)-to-dG(C2).

Assessment of the genotoxic potential of nitric oxide-induced guanine lesions by in vitro reactions with Escherichia coli DNA polymerase I

It has been suggested that carcinogenesis associated with chronic inflammation involves DNA damage by nitric oxide (NO) and other reactive species secreted from macrophages and neutrophils. The guanine moiety of DNA reacts with NO, yielding two major deamination products: xanthine (Xan) and oxanine (Oxa). Oxa reacts further with polyamines and DNA binding proteins to form cross-link adducts. In the present study, we characterized the structure of the cross-link adducts of Oxa with spermine (Oxa-Sp). Spectrometric analysis of Oxa-Sp adducts showed that they are ring-opened adducts of Oxa covalently bonded to the terminal amino (major product) and internal imino (minor product) groups of spermine. To assess genotoxic potential, Xan, Oxa, Oxa-Sp and an abasic (AP) site were site specifically incorporated into oligonucleotide templates. These lesions differentially blocked in vitro DNA synthesis catalyzed by DNA polymerase I Klenow fragment (Pol I Kf). The relative efficiency of translesion synthesis was G (1) > Oxa (0.19) > Xan (0.12) > AP (0.088) > Oxa-Sp (0.035). Primer extension assays with a single nucleotide and Pol I Kf revealed that non-mutagenic dCMP was inserted most efficiently opposite Xan and Oxa, with the extent of primer elongation being 65% for Xan and 68% for Oxa. However, mutagenic nucleotides were also inserted. The extent of primer elongation for Xan was 16% with dTMP and 14% with dGMP, whereas that for Oxa was 49% with dTMP. For Oxa-Sp, mutagenic dAMP (13%) was preferentially inserted. Accordingly, when generated in vivo, Xan and Oxa would constitute moderate blocks to DNA synthesis and primarily elicit G:C to A:T transitions when bypassed, whereas Oxa-Sp would strongly block DNA synthesis and elicit G:C to T:A transversions.

Repair activity of base and nucleotide excision repair enzymes for guanine lesions induced by nitrosative stress

Nitric oxide (NO) induces deamination of guanine, yielding xanthine and oxanine (Oxa). Furthermore, Oxa reacts with polyamines and DNA binding proteins to form cross-link adducts. Thus, it is of interest how these lesions are processed by DNA repair enzymes in view of the genotoxic mechanism of NO. In the present study, we have examined the repair capacity for Oxa and Oxa–spermine cross-link adducts (Oxa–Sp) of enzymes involved in base excision repair (BER) and nucleotide excision repair (NER) to delineate the repair mechanism of nitrosative damage to guanine. Oligonucleotide substrates containing Oxa and Oxa–Sp were incubated with purified BER and NER enzymes or cell-free extracts (CFEs), and the damage-excising or DNA-incising activity was compared with that for control (physiological) substrates. The Oxa-excising activities of Escherichia coli and human DNA glycosylases and HeLa CFEs were 0.2–9% relative to control substrates, implying poor processing of Oxa by BER. In contrast, DNA containing Oxa–Sp was incised efficiently by UvrABC nuclease and SOS-induced E.coli CFEs, suggesting a role of NER in ameliorating genotoxic effects associated with nitrosative stress. Analyses of the activity of CFEs from NER-proficient and NER-deficient human cells on Oxa–Sp DNA confirmed further the involvement of NER in the repair of nitrosative DNA damage.

Human DNA glycosylases involved in the repair of oxidatively damaged DNA

Reactive oxygen species from endogenous and environmental sources induce oxidative damage to DNA, and hence pose an enormous threat to the genetic integrity of cells. Such oxidative DNA damage is restored by the base excision repair (BER) pathway that is conserved from bacteria to humans and is initiated by DNA glycosylases, which simply remove the aberrant base from the DNA backbone by hydrolyzing the N-glycosidic bond (monofunctional DNA glycosylase), or further catalyze the incision of a resulting abasic site (bifunctional DNA glycosylase). In human cells, oxidative pyrimidine lesions are generally removed by hNTH1, hNEIL1, or hNEIL2, whereas oxidative purine lesions are removed by hOGG1. hSMUG1 excises a subset of oxidative base damage that is poorly recognized by the above enzymes. Unlike these enzymes, hMYH removes intact A misincorporated opposite template 8-oxoguanine during DNA replication. Although hNTH1, hOGG1, and hMYH account for major cellular glycosylase activity for inherent substrate lesions, mouse models deficient in the enzymes exhibit no overt phenotypes such as the development of cancer, implying backup mechanisms. Contrary to the mouse model, hMYH mutations have been shown to lead to a multiple colorectal adenoma syndrome and high colorectal cancer risk. For cleavage of the N-glycosidic bond, bifunctional DNA glycosylases (hNTH1, hNEIL1, hNEIL2, and hOGG1) use Lys or Pro for direct attack on sugar C1', whereas monofunctional DNA glycosylases (hSMUG1 and hMYH) use an activated water molecule. DNA glycosylases for oxidative damage, if not all, are covalently trapped by DNA containing 2-deoxyribonolactone or oxanine. Thus, the depletion of functional DNA glycosylases using covalent trapping may reduce the BER capacity of cancer cells, hence potentiating the efficacy of anticancer drugs or radiation therapy.

5-Cyanoimino-4-oxomethylene-4,5-dihydroimidazole and 5-Cyanoamino-4-imidazolecarboxylic Acid Intermediates in Nitrosative Guanosine Deamination: Evidence from 18O-Labeling Experiments

The nitrosative deaminations (37 degrees C, NaNO2, NaAc buffer, pH 3.7) of guanosine 1r in (18O)water (97.6%) and of [6-18O]-1r in normal water were studied. [6-(18)O]-1r was prepared from 2-amino-6-chloropurine riboside using adenosine deaminase. The reaction products xanthosine 3r and oxanosine 4r were separated by HPLC and characterized by LC/MS analysis and 13C NMR spectroscopy. The 18O-isotopic shifts on the 13C NMR signals were measured and allowed the identification of all isotopomers formed. The results show that oxanosine is formed via 5-cyanoimino-4-oxomethylene-4,5-dihydroimidazole, 5, and its 1,4-addition product 5-cyanoamino-4-imidazolecarboxylic acid, 6. This hydration of 5 to 6 leads to aromatization and greatly dominates over water addition to the cyanoimino group of 5 to form 5-guanidinyliden-4-oxomethylene-4,5-dihydroimidazole, 7. 5-Guanidinyl-4-imidazolecarboxylic acid, 8, the product of water addition to 6, is not involved.

Oxanine DNA glycosylase activity from Mammalian alkyladenine glycosylase

Oxanine (Oxa) is a deaminated base lesion derived from guanine in which the N(1)-nitrogen is substituted by oxygen. This work reports the mutagenicity of oxanine as well as oxanine DNA glycosylase (ODG) activities in mammalian systems. Using human DNA polymerase beta, deoxyoxanosine triphosphate is only incorporated opposite cytosine (Cyt). When an oxanine base is in a DNA template, Cyt is efficiently incorporated opposite the template oxanine; however, adenine and thymine are also incorporated opposite Oxa with an efficiency approximately 80% of a Cyt/Oxa (C/O) base pair. Guanine is incorporated opposite Oxa with the least efficiency, 16% compared with cytosine. ODG activity was detected in several mammalian cell extracts. Among the known human DNA glycosylases tested, human alkyladenine glycosylase (AAG) shows ODG activity, whereas hOGG1, hNEIL1, or hNEIL2 did not. ODG activity was detected in spleen cell extracts of wild type age-matched mice, but little activity was observed in that of Aag knock-out mice, confirming that the ODG activity is intrinsic to AAG. Human AAG can excise Oxa from all four Oxa-containing double-stranded base pairs, Cyt/Oxa, Thy/Oxa, Ade/Oxa, and Gua/Oxa, with no preference to base pairing. Surprisingly, AAG can remove Oxa from single-stranded Oxa-containing DNA as well. Indeed, AAG can also remove 1,N(6)-ethenoadenine from single-stranded DNA. This study extends the deaminated base glycosylase activities of AAG to oxanine; thus, AAG is a mammalian enzyme that can act on all three purine deamination bases, hypoxanthine, xanthine, and oxanine.

Differential Specificity of Human and Escherichia coli Endonuclease III and VIII Homologues for Oxidative Base Lesions

In human cells, oxidative pyrimidine lesions are restored by the base excision repair pathway initiated by homologues of Endo III (hNTH1) and Endo VIII (hNEIL1 and hNEIL2). In this study we have quantitatively analyzed and compared their activity toward nine oxidative base lesions and an apurinic/apyrimidinic (AP) site using defined oligonucleotide substrates. hNTH1 and hNEIL1 but not hNEIL2 excised the two stereoisomers of thymine glycol (5R-Tg and 5S-Tg), but their isomer specificity was markedly different: the relative activity for 5R-Tg:5S-Tg was 13:1 for hNTH1 and 1.5:1 for hNEIL1. This was also the case for their Escherichia coli homologues: the relative activity for 5R-Tg:5S-Tg was 1:2.5 for Endo III and 3.2:1 for Endo VIII. Among other tested lesions for hNTH1, an AP site was a significantly better substrate than urea, 5-hydroxyuracil (hoU), and guanine-derived formamidopyrimidine (mFapyG), whereas for hNEIL1 these base lesions and an AP site were comparable substrates. In contrast, hNEIL2 recognized an AP site exclusively, and the activity for hoU and mFapyG was marginal. hNEIL1, hNEIL2, and Endo VIII but not hNTH1 and Endo III formed cross-links to oxanine, suggesting conservation of the -fold of the active site of the Endo VIII homologues. The profiles of the excision of the Tg isomers with HeLa and E. coli cell extracts closely resembled those of hNTH1 and Endo III, confirming their major contribution to the repair of Tg isomers in cells. However, detailed analysis of the cellular activity suggests that hNEIL1 has a significant role in the repair of 5S-Tg in human cells.

5-Cyanoimino-4-oxomethylene-4,5-dihydroimidazole and Nitrosative Guanine Deamination. A Theoretical Study of Geometries, Electronic Structures, and N-Protonation

The 5-cyanoimino-4-oxomethylene-4,5-dihydroimidazole 1 (R = H), its N1-derivatives 2 (R = Me) and 3 (R = MOM) and their cyano-N (4, 6, 8) and imino-N protonated (5, 7, 9) derivatives were studied with RHF, B3LYP, and MP2 theory. Solvation effects were estimated with the isodensity polarized continuum model (IPCM) at the MP2 level using the dielectric constant of water. Carbodiimide 10, cyanamide 12, N-cyanomethyleneimine 13, and its protonated derivatives 14 and 15 were considered for comparison as well. Adequate theoretical treatment requires the inclusion of dispersion because of the presence of intramolecular van der Waals, charge-dipole, and dipole-dipole (including H-bonding) interactions. All conformers were considered for the MOM-substituted systems, and direct consequences on the preferred site of protonation were found. The vicinal push (oxomethylene)-pull (cyanoimino) pattern of the 5-cyanoimino-4-oxomethylene-4,5-dihydroimidazoles results in the electronic structure of aromatic imidazoles with 4-acylium and 5-cyanoamido groups. The gas-phase proton affinities of 1-3 are over 30 kcal/mol higher than that for N-cyanomethyleneimine 13, and this result provides compelling evidence in support of the zwitterionic character of 1-3. Protonation enhances the push-pull interaction; the OC charge is increased from about one-half in 1-3 to about two-thirds in the protonated systems. In the gas phase, cyano-N protonation is generally preferred but imino-N protonation can compete if the R-group contains a suitable heteroatom (hydrogen-bond acceptor, Lewis base). In polar solution, however, imino-N protonation is generally preferred. Solvation has a marked consequence on the propensity for protonation. Whereas protonation is fast and exergonic in the gas phase, it is endergonic in the polar condensed phase. It is an immediate consequence of this result that the direct observation of the cations 8 and 9 should be possible in the gas phase only.

DNA-protein cross-link formation mediated by oxanine. A novel genotoxic mechanism of nitric oxide-induced DNA damage

Chronic inflammation is a risk factor for many human cancers, and nitric oxide (NO) produced in inflamed tissues has been proposed to cause DNA damage via nitrosation or oxidation of base moieties. Thus, NO-induced DNA damage could be relevant to carcinogenesis associated with chronic inflammation. In this report, we report a novel genotoxic mechanism of NO that involves DNA-protein cross-links (DPCs) induced by oxanine (Oxa), a major NO-induced guanine lesion. When a duplex DNA containing Oxa at the site-specific position was incubated with DNA-binding proteins such as histone, high mobility group (HMG) protein, and DNA glycosylases, DPCs were formed between Oxa and protein. The rate of DPC formation with DNA glycosylases was approximately two orders of magnitude higher than that with histone and HMG protein. Analysis of the reactivity of individual amino acids to Oxa suggested that DPC formation occurred between Oxa and side chains of lysine or arginine in the protein. A HeLa cell extract also gave rise to two major DPCs when incubated with DNA-containing Oxa. These results reveal a dual aspect of Oxa as causal damage of DPC formation and as a suicide substrate of DNA repair enzymes, both of which could pose a threat to the genetic and structural integrity of DNA, hence potentially leading to carcinogenesis.

Novel repair activities of AlkA (3-methyladenine DNA glycosylase II) and endonuclease VIII for xanthine and oxanine, guanine lesions induced by nitric oxide and nitrous acid

Nitrosation of guanine in DNA by nitrogen oxides such as nitric oxide (NO) and nitrous acid leads to formation of xanthine (Xan) and oxanine (Oxa), potentially cytotoxic and mutagenic lesions. In the present study, we have examined the repair capacity of DNA N-glycosylases from Escherichia coli for Xan and Oxa. The nicking assay with the defined substrates containing Xan and Oxa revealed that AlkA [in combination with endonuclease (Endo) IV] and Endo VIII recognized Xan in the tested enzymes. The activity (V(max)/K(m)) of AlkA for Xan was 5-fold lower than that for 7-methylguanine, and that of Endo VIII was 50-fold lower than that for thymine glycol. The activity of AlkA and Endo VIII for Xan was further substantiated by the release of [(3)H]Xan from the substrate. The treatment of E.coli with N-methyl-N'-nitro-N-nitrosoguanidine increased the Xan-excising activity in the cell extract from alkA(+) but not alkA(-) strains. The alkA and nei (the Endo VIII gene) double mutant, but not the single mutants, exhibited increased sensitivity to nitrous acid relative to the wild type strain. AlkA and Endo VIII also exhibited excision activity for Oxa, but the activity was much lower than that for Xan.

Formation of a fairly stable diazoate intermediate of 5-methyl-2'-deoxycytidine by HNO2 and NO, and its implication to a novel mutation mechanism in CpG site

The intermediate produced from 5-methyl-2'-deoxycytidine ((5me)dCyd) by HNO2 and NO treatments was isolated and characterized. When 10mM (5me)dCyd was incubated with 100mM NaNO2 at pH 3.7 and 37 degrees C, a previously unidentified product was formed. The product was identified as a diazoate derivative of (5me)dCyd, 1-(beta-D-2'-deoxyribofuranosyl)-5-methyl-2-oxopyrimidine-4-diazoate ((5me)dCyd-diazoate), on the bases of several measurements including LC/MS. The time course of the concentration change of the diazoate showed a characteristic profile of a reaction intermediate, and the steady state concentration was 2.3 microM (0.023% yield). When an aqueous solution of 10mM (5me)dCyd (10 mL) was bubbled by NO at 37 degrees C under aerobic conditions holding the pH around 7.4, the diazoate was also generated. The yield of the diazoate was 0.041 micromol (0.041% yield) at 20 mmol of NO absorption. At physiological pH and temperature (pH 7.4, 37 degrees C), the diazoate was converted to dThd exclusively with a first order rate constant k=9.1x10(-6) x s(-1) (t(1/2)=21 h). These results show that the diazoate is generated as a relatively stable intermediate in the reactions of (5me)dCyd with HNO2 and NO and further suggest that the diazoate can be formed in cellular DNA with biologically relevant doses of HNO2 and NO.

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.

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.

Formation of 2-chloroinosine from guanosine by treatment of HNO(2) in the presence of NaCl

We investigated the reaction of Guo with nitrous acid in the presence of NaCl. When 1 mM Guo was incubated with 100 mM NaNO(2) and 2M NaCl in sodium acetate buffer at pH 3.2 and 37 degrees C, 2-chloroinosine (2-Cl-Ino) was produced in addition to oxanosine (Oxo) and xanthosine (Xao). The yield of 2-Cl-Ino was 0.033 mM at an incubation time of 2 h. Under the same reaction conditions, GMP and dGuo gave rise to the corresponding 2-chloro derivatives with comparable yields. All the 2-chloro derivatives were fairly stable (t(12)>360 h) at physiological pH and temperature. To elucidate the reaction mechanism of the chlorination, the diazoate derivative of Guo, a reaction intermediate of the Guo-HNO(2) system, was employed as a starting compound. When the diazoate was incubated with 2M NaCl in a neutral solution, 2-Cl-Ino was produced in addition to Oxo and Xao. These results suggest that the 2-chloro derivatives can be produced from foodstuffs in the human stomach and may have potential importance as a carcinogen causing gastric cancer.