guanidinohydantoin and 8-hydroxyguanine

Reactive oxygen species, both endogenous and exogenous, can damage nucleobases of RNA and DNA. Among the nucleobases, guanine has the lowest redox potential, making it a major target of oxidation. Although RNA is more prone to oxidation than DNA is, oxidation of guanine in RNA has been studied to a significantly lesser extent. One of the reasons for this is that many tools that were previously developed to study oxidation of DNA cannot be used on RNA. In the study presented here, the lack of a method for seeking sites of modification in RNA where oxidation occurs is addressed. For this purpose, reverse transcription of RNA containing major products of guanine oxidation was used. Extension of a DNA primer annealed to an RNA template containing 8-oxo-7,8-dihydroguanine (OG), 5-guanidinohydantoin (Gh), or the R and S diastereomers of spiroiminodihydantoin (Sp) was studied under standing start conditions. SuperScript III reverse transcriptase is capable of bypassing these lesions in RNA inserting predominantly A opposite OG, predominantly G opposite Gh, and almost an equal mixture of A and G opposite the Sp diastereomers. These data should allow RNA sequencing of guanine oxidation products by following characteristic mutation signatures formed by the reverse transcriptase during primer elongation past G oxidation sites in the template RNA strand.

Topics: Adenine; Guanidines; Guanine; Guanosine; Hydantoins; Kinetics; Oxidation-Reduction; Reverse Transcription; RNA; RNA-Directed DNA Polymerase; Spiro Compounds; Stereoisomerism

G-quadruplex is a four-stranded G-rich DNA structure that is highly susceptible to oxidation. Despite the important roles that G-quadruplexes play in telomere biology and gene transcription, neither the impact of guanine lesions on the stability of quadruplexes nor their repair are well understood. Here, we show that the oxidized guanine lesions 8-oxo-7,8-dihydroguanine (8-oxoG), guanidinohydantoin (Gh) and spiroiminodihydantoin (Sp) reduce the thermostability and alter the folding of telomeric quadruplexes in a location-dependent manner. Also, the NEIL1 and NEIL3 DNA glycosylases can remove hydantoin lesions but none of the glycosylases, including OGG1, are able to remove 8-oxoG from telomeric quadruplexes. Interestingly, a hydantoin lesion at the site most prone to oxidation in quadruplex DNA is not efficiently removed by NEIL1 or NEIL3. However, NEIL1, NEIL2 and NEIL3 remove hydantoins from telomeric quadruplexes formed by five TTAGGG repeats much more rapidly than the commonly studied four-repeat quadruplex structures. We also show that APE1 cleaves furan in selected positions in Na(+)-coordinated telomeric quadruplexes. In promoter G-quadruplex DNA, the NEIL glycosylases primarily remove Gh from Na(+)-coordinated antiparallel quadruplexes but not K(+)-coordinated parallel quadruplexes containing VEGF or c-MYC promoter sequences. Thus, the NEIL DNA glycosylases may be involved in both telomere maintenance and in gene regulation.

Topics: DNA; DNA Glycosylases; DNA-(Apurinic or Apyrimidinic Site) Lyase; Furans; G-Quadruplexes; Guanidines; Guanine; Guanosine; Humans; Hydantoins; N-Glycosyl Hydrolases; Oxidation-Reduction; Potassium; Promoter Regions, Genetic; Sodium; Spiro Compounds; Telomere

Exogenously and endogenously produced reactive oxygen species attack the base and sugar moieties of DNA showing a preference for reaction at 2'-deoxyguanosine (dG) sites. In the present work, dG was oxidized by HO(•) via the Fe(II)-Fenton reaction or by X-ray radiolysis of water. The oxidized lesions observed include the 2'-deoxynucleosides of 8-oxo-7,8-dihydroguanine (dOG), spiroiminodihydantoin (dSp), 5-guanidinohydantoin (dGh), oxazolone (dZ), 5-carboxamido-5-formamido-2-iminohydantoin (d2Ih), 5',8-cyclo-2'-deoxyguanosine (cyclo-dG), and the free base guanine (Gua). Reactions conducted with ascorbate or N-acetylcysteine as a reductant under aerobic conditions identified d2Ih as the major lesion formed. Studies were conducted to identify the role of O2 and the reductant in product formation. From these studies, mechanisms are proposed to support d2Ih as a major oxidation product detected under aerobic conditions in the presence of the reductant. These nucleoside observations were then validated in oxidations of oligodeoxynucleotide and λ-DNA contexts that demonstrated high yields of d2Ih in tandem with dOG, dSp, and dGh. These results identify dG oxidation to d2Ih to occur in high yields leading to a hypothesis that d2Ih could be found from in cells stressed with HO(•). Further, the distorted ring structure of d2Ih likely causes this lesion to be highly mutagenic.

Topics: Deoxyguanosine; DNA; Guanidines; Guanine; Hydantoins; Iron; Molecular Structure; Nucleosides; Oxazolone; Oxidation-Reduction; Oxygen; X-Rays

The unzipping kinetics for lesion-containing DNA duplexes was studied in an α-hemolysin (α-HL) nanopore. The lesion of focus was the guanine two-electron oxidation product, 8-oxo-7,8-dihydroguanine (OG), and its further oxidation products, the hydantoins guanidinohydantoin (Gh) and spiroiminodihydantoin (Sp). The voltage-driven unzipping of individual duplex DNA molecules with symmetrical overhangs was carried out by pulling one strand of the duplex through the α-HL channel using an electrical field. Entry from the 3' or 5' end produced distinct current blockages, allowing directional effects on unzipping kinetics to be investigated. We find that the strand dissociation of complementary duplexes or duplexes containing the slightly destabilizing lesion OG follows a first-order kinetic model, while opening of duplexes that contain the highly destabilizing lesions Gh or Sp is described by two sequential first-order reactions, in which the intermediate state is proposed to correspond to the duplex unzipped to the lesion site within the channel. The rate constants for strand separation of the duplexes containing single lesions were obtained from kinetic model fits to histograms of unzipping duration. For all duplexes, the rate constants for strand separation displayed a significant dependence on the direction of entry into the nanopore. For duplexes containing Gh, truncated duplexes were used to assign the measured rate constants for the first and second unzipping steps of symmetrically designed duplexes.

Topics: DNA; DNA Damage; DNA Repair; Guanidines; Guanine; Hemolysin Proteins; Hydantoins; Kinetics; Nanopores; Oxidation-Reduction

Guanidinohydantoin (Gh) is a hyperoxidized DNA lesion produced by oxidation of 8-oxo-7,8-dihydroguanine (8-oxoG). Previous work has shown that Gh is potently mutagenic in both in vitro and in vivo coding for G → T and G → C transversion mutations. In this work, analysis by circular dichroism shows that the Gh lesion does not significantly alter the global structure of a 15-mer duplex and that the DNA remains in the B-form. However, we find that Gh causes a large decrease in the thermal stability, decreasing the duplex melting temperature by ~17 °C relative to an unmodified duplex control. Using optical melting analysis and differential scanning calorimetry, the thermodynamic parameters describing duplex melting were also determined. We find that the Gh lesion causes a dramatic decrease in the enthalpic stability of the duplex. This enthalpic destabilization is somewhat tempered by entropic stabilization; yet, Gh results in an overall decrease in thermodynamic stability of the duplex relative to a control that lacks DNA damage, with a ΔΔG° of -7 kcal/mol. These results contribute to our understanding of the consequences of hyperoxidation of G and provide insight into how the thermal and thermodynamic destabilization caused by Gh may influence replication and/or repair of the lesion.

Topics: Calorimetry, Differential Scanning; Circular Dichroism; DNA; Guanidines; Guanine; Hydantoins; Oxidation-Reduction; Thermodynamics; Transition Temperature

8-Oxo-7,8-dihydroguanine (8-hydroxyguanine) is oxidized more easily than normal nucleobases, which can produce spiroiminodihydantoin (Sp) and guanidinohydantoin (Gh). These secondary oxidation products of 8-oxo-7,8-dihydroguanine are highly mutagenic when formed within DNA. To evaluate the mutagenicity of the corresponding oxidation products of 8-oxo-7,8-dihydro-2'-deoxyguanosine 5'-triphosphate (8-hydroxy-2'- deoxyguanosine 5'-triphosphate) in the nucleotide pool, Escherichia coli cells deficient in the mutT gene were treated with H(2)O(2), and the induced mutations were analyzed. Moreover, the 2'-deoxyriboside 5'-triphosphate derivatives of Sp and Gh were also introduced into competent E. coli cells. The H(2)O(2) treatment of mutT E. coli cells resulted in increase of G:C → T:A and A:T → T:A mutations. However, the incorporation of exogenous Sp and Gh 2'-deoxyribonucleotides did not significantly increase the mutation frequency. These results suggested that the oxidation product(s) of 8-oxo-7,8-dihydro-2'-deoxyguanosine 5'-triphosphate induces G:C → T:A and A:T → T:A mutations, and that the 2'-deoxyriboside 5'-triphosphate derivatives of Sp and Gh exhibit quite weak mutagenicity, in contrast to the bases in DNA.

Topics: Deoxyguanine Nucleotides; Escherichia coli; Escherichia coli Proteins; Guanidines; Guanine; Guanosine; Guanosine Triphosphate; Hydantoins; Hydrogen Peroxide; Mutagens; Oxidation-Reduction; Spiro Compounds

Formamidopyrimidine DNA glycosylase (Fpg) and endonuclease VIII (Nei) share an overall common three-dimensional structure and primary amino acid sequence in conserved structural motifs but have different substrate specificities, with bacterial Fpg proteins recognizing formamidopyrimidines, 8-oxoguanine (8-oxoG) and its oxidation products guanidinohydantoin (Gh), and spiroiminodihydantoin (Sp) and bacterial Nei proteins recognizing primarily damaged pyrimidines. In addition to bacteria, Fpg has also been found in plants, while Nei is sparsely distributed among the prokaryotes and eukaryotes. Phylogenetic analysis of Fpg and Nei DNA glycosylases demonstrated, with 95% bootstrap support, a clade containing exclusively sequences from plants and fungi. Members of this clade exhibit sequence features closer to bacterial Fpg proteins than to any protein designated as Nei based on biochemical studies. The Candida albicans (Cal) Fpg DNA glycosylase and a previously studied Arabidopsis thaliana (Ath) Fpg DNA glycosylase were expressed, purified and characterized. In oligodeoxynucleotides, the preferred glycosylase substrates for both enzymes were Gh and Sp, the oxidation products of 8-oxoG, with the best substrate being a site of base loss. GC/MS analysis of bases released from gamma-irradiated DNA show FapyAde and FapyGua to be excellent substrates as well. Studies carried out with oligodeoxynucleotide substrates demonstrate that both enzymes discriminated against A opposite the base lesion, characteristic of Fpg glycosylases. Single turnover kinetics with oligodeoxynucleotides showed that the plant and fungal glycosylases were most active on Gh and Sp, less active on oxidized pyrimidines and exhibited very little or no activity on 8-oxoG. Surprisingly, the activity of AthFpg1 on an AP site opposite a G was extremely robust with a k(obs) of over 2500min(-1).

Topics: Arabidopsis; Arabidopsis Proteins; Candida albicans; Deoxyribonuclease (Pyrimidine Dimer); DNA Glycosylases; DNA-Formamidopyrimidine Glycosylase; DNA, Bacterial; DNA, Plant; Gamma Rays; Gas Chromatography-Mass Spectrometry; Guanidines; Guanine; Guanosine; Hydantoins; Kinetics; Pyrimidines; Spiro Compounds

The potential energy surface for formation of 2-amino-5-hydroxy-7,9-dihydropurine-6,8-dione (5-OH-OG), guanidinohydantoin (Gh) and spiroiminodihydantoin (Sp) from 8-oxoguanine (8-oxoG) has been mapped out using B3LYP density functional theory, the aug-cc-pVTZ and 6-31+G(d,p) basis sets and the IEF-polarizable continuum model (PCM) solvation model. Three pathways for formation of 5-OH-OG from 8-oxoG were evaluated: (A) stepwise loss of two electrons and two protons to form the quinonoid intermediate 2-amino-7,9-dihydro-purine-6,8-dione (8-oxoG(ox)) followed by hydration; (B) stepwise loss of two electrons and one proton and net addition of hydroxide, in which the key step is nucleophilic addition to the 8-oxoG radical cation; and (C) stepwise loss of one electron and one proton and addition of hydroxyl radical to the 8-oxoG radical cation. The data suggest that all three pathways are energetically feasible mechanisms for the formation of 5-OH-OG, however, Pathway A may be kinetically favored over Pathway B. Although lower in energy, Pathway C may be of limited biological significance since it depends on the local concentration of hydroxyl radical. Pathways for hydrolysis and decarboxylation of 5-OH-OG to form Gh via either a carboxylic acid or substituted carbamic acid intermediate have been evaluated with the result that cleavage of the N1-C6 bond is clearly favored over that of the C5-C6 bond. Formation of Sp from 5-OH-OG via stepwise proton transfer and acyl migration or ring opening followed by proton transfer and ring closure have also been explored and suggest that deprotonation of the hydroxyl group facilitates a 1,2 acyl shift. Results of the calculations are consistent with experimental studies showing dependence of the Gh/Sp product ratio on pH. Under neutral and basic conditions, the data predict that formation of Sp is kinetically favored over the pathways for formation of Gh. Under acidic conditions, Gh is predicted to be the kinetically favored product.

Topics: Guanidines; Guanine; Guanosine; Hydantoins; Models, Chemical; Models, Molecular; Molecular Structure; Phase Transition; Solutions; Spiro Compounds; Water

Oxidative damage to DNA by endogenous and exogenous reactive oxygen species has been directly linked to cancer, aging, and a variety of neurological disorders. The potential mutagenicity of the primary guanine oxidation product 8-oxo-7,8-dihydroguanine (Og) has been studied intensively, and much information is available about its miscoding potential in vitro and in vivo. Recently, a variety of DNA lesions have been identified as oxidation products of both guanine and 8-oxoguanine, among them spiroiminodihydantoin (Sp) and guanidinohydantoin (Gh). To address questions concerning the mutagenic potential of these secondary products of guanine oxidation, the effect of the lesions on proofreading by DNA polymerase was studied in vitro using the Klenow fragment of Escherichia coli polymerase I (Kf exo+). For the first time, k(cat)/K(m) values were obtained for proofreading of the X:N mismatches (X = Og, Gh, or Sp; N = A, G, or C). Proofreading studies of the terminal mismatches demonstrated the significance of the sequence context flanking the lesion on the 3' side. In addition, a sequence dependence was observed for Gh based on the identity of the base on the 5' side of the lesion providing evidence for a primer slippage mode if N was complementary to the 5' base. Internal mismatches were recognized by Kf exo+ resulting in the excision of the correct base pairs flanking mismatches from the 5' side. The absence of a sequence effect for the Gh- and Sp-containing duplexes can be attributed to the severe destabilization of the lesion-containing duplexes that promotes interaction with the exonuclease domain of the Klenow fragment.

Topics: AT Rich Sequence; Base Pair Mismatch; DNA Polymerase I; DNA Primers; Escherichia coli Proteins; GC Rich Sequence; Guanidines; Guanine; Guanosine; Hydantoins; Kinetics; Nucleic Acid Heteroduplexes; Oxidation-Reduction; Spiro Compounds; Substrate Specificity; Templates, Genetic; Thermodynamics

8-oxoguanine (8-oxoG), induced by reactive oxygen species and arguably one of the most important mutagenic DNA lesions, is prone to further oxidation. Its one-electron oxidation products include potentially mutagenic guanidinohydantoin (Gh) and spiroiminodihydantoin (Sp) because of their mispairing with A or G. All three oxidized base-specific DNA glycosylases of Escherichia coli, namely endonuclease III (Nth), 8-oxoG-DNA glycosylase (MutM) and endonuclease VIII (Nei), excise Gh and Sp, when paired with C or G in DNA, although Nth is less active than the other two. MutM prefers Sp and Gh paired with C (kcat/K(m) of 0.24-0.26 min(-1) x nM(-1)), while Nei prefers G over C as the complementary base (k(cat)/K(m) - 0.15-0.17 min(-1) x nM(-1)). However, only Nei efficiently excises these paired with A. MutY, a 8-oxoG.A(G)-specific A(G)-DNA glycosylase, is inactive with Gh(Sp).A/G-containing duplex oligonucleotide, in spite of specific affinity. It inhibits excision of lesions by MutM from the Gh.G or Sp.G pair, but not from Gh.C and Sp.C pairs. In contrast, MutY does not significantly inhibit Nei for any Gh(Sp) base pair. These results suggest a protective function for MutY in preventing mutation as a result of A (G) incorporation opposite Gh(Sp) during DNA replication.

Topics: Deoxyribonuclease (Pyrimidine Dimer); DNA Glycosylases; DNA Repair; DNA-Formamidopyrimidine Glycosylase; Electrons; Endodeoxyribonucleases; Enzyme Inhibitors; Escherichia coli; Escherichia coli Proteins; Guanidines; Guanine; Guanosine; Hydantoins; Kinetics; N-Glycosyl Hydrolases; Oxidation-Reduction; Protein Binding; Schiff Bases; Spiro Compounds; Substrate Specificity