Marc M. Greenberg

Repair of Formamidopyrimidines in DNA Involves Different Glycosylases ROLE OF THE OGG1, NTH1, AND NEIL1 ENZYMES

The oxidatively induced DNA lesions 2,6-diamino-4-hydroxy-5-formamidopyrimidine (FapyG) and 4,6-diamino-5-formamidopyrimidine (FapyA) are formed abundantly in DNA of cultured cells or tissues exposed to ionizing radiation or to other free radical-generating systems. In vitro studies indicate that these lesions are miscoding, can block the progression of DNA polymerases, and are substrates for base excision repair. However, no study has yet addressed how these lesions are metabolized in cellular extracts. The synthesis of oligonucleotides containing FapyG and FapyA at defined positions was recently reported. These constructs allowed us to investigate the repair of Fapy lesions in nuclear and mitochondrial extracts from wild type and knock-out mice lacking the two major DNA glycosylases for repair of oxidative DNA damage, OGG1 and NTH1. The background level of FapyG/FapyA in DNA from these mice was also determined. Endogenous FapyG levels in liver DNA from wild type mice were significantly higher than 8-hydroxyguanine levels. FapyG and FapyA were efficiently repaired in nuclear and mitochondrial extracts from wild type animals but not in the glycosylase-deficient mice. Our results indicated that OGG1 and NTH1 are the major DNA glycosylases for the removal of FapyG and FapyA, respectively. Tissue-specific analysis suggested that other DNA glycosylases may contribute to FapyA repair when NTH1 is poorly expressed. We identified NEIL1 in liver mitochondria, which could account for the residual incision activity in the absence of OGG1 and NTH1. FapyG and FapyA levels were significantly elevated in DNA from the knock-out mice, underscoring the biological role of OGG1 and NTH1 in the repair of these lesions.

Mechanistic studies on DNA damage by minor groove binding copper–phenanthroline conjugates

Copper–phenanthroline complexes oxidatively damage and cleave nucleic acids. Copper bis-phenanthroline and copper complexes of mono- and bis-phenanthroline conjugates are used as research tools for studying nucleic acid structure and binding interactions. The mechanism of DNA oxidation and cleavage by these complexes was examined using two copper–phenanthroline conjugates of the sequence-specific binding molecule, distamycin. The complexes contained either one or two phenanthroline units that were bonded to the DNA-binding domain through a linker via the 3-position of the copper ligand. A duplex containing independently generated 2-deoxyribonolactone facilitated kinetic analysis of DNA cleavage. Oxidation rate constants were highly dependent upon the ligand environment but rate constants describing elimination of the alkali-labile 2-deoxyribonolactone intermediate were not. Rate constants describing DNA cleavage induced by each molecule were 11–54 times larger than the respective oxidation rate constants. The experiments indicate that DNA cleavage resulting from β-elimination of 2-deoxyribonolactone by copper–phenanthroline complexes is a general mechanism utilized by this family of molecules. In addition, the experiments confirm that DNA damage mediated by mono- and bis-phenanthroline copper complexes proceeds through distinct species, albeit with similar outcomes.

The Human Werner Syndrome Protein Stimulates Repair of Oxidative DNA Base Damage by the DNA Glycosylase NEIL1

The mammalian DNA glycosylase, NEIL1, specific for repair of oxidatively damaged bases in the genome via the base excision repair pathway, is activated by reactive oxygen species and prevents toxicity due to radiation. We show here that the Werner syndrome protein (WRN), a member of the RecQ family of DNA helicases, associates with NEIL1 in the early damage-sensing step of base excision repair. WRN stimulates NEIL1 in excision of oxidative lesions from bubble DNA substrates. The binary interaction between NEIL1 and WRN (KD = 60 nm) involves C-terminal residues 288-349 of NEIL1 and the RecQ C-terminal (RQC) region of WRN, and is independent of the helicase activity WRN. Exposure to oxidative stress enhances the NEIL-WRN association concomitant with their strong nuclear co-localization. WRN-depleted cells accumulate some prototypical oxidized bases (e.g. 8-oxoguanine, FapyG, and FapyA) indicating a physiological function of WRN in oxidative damage repair in mammalian genomes. Interestingly, WRN deficiency does not have an additive effect on in vivo damage accumulation in NEIL1 knockdown cells suggesting that WRN participates in the same repair pathway as NEIL1.

Rapid DNA–protein cross-linking and strand scission by an abasic site in a nucleosome core particle

Apurinic/apyrimidinic (AP) sites are ubiquitous DNA lesions that are highly mutagenic and cytotoxic if not repaired. In addition, clusters of two or more abasic lesions within one to two turns of DNA, a hallmark of ionizing radiation, are repaired much less efficiently and thus present greater mutagenic potential. Abasic sites are chemically labile, but naked DNA containing them undergoes strand scission slowly with a half-life on the order of weeks. We find that independently generated AP sites within nucleosome core particles are highly destabilized, with strand scission occurring ∼60-fold more rapidly than in naked DNA. The majority of core particles containing single AP lesions accumulate DNA–protein cross-links, which persist following strand scission. The N-terminal region of histone protein H4 contributes significantly to DNA–protein cross-links and strand scission when AP sites are produced approximately 1.5 helical turns from the nucleosome dyad, which is a known hot spot for nucleosomal DNA damage. Reaction rates for AP sites at two positions within this region differ by ∼4-fold. However, the strand scission of the slowest reacting AP site is accelerated when it is part of a repair resistant bistranded lesion composed of two AP sites, resulting in rapid formation of double strand breaks in high yields. Multiple lysine residues within a single H4 protein catalyze double strand cleavage through a mechanism believed to involve a templating effect. These results show that AP sites within the nucleosome produce significant amounts of DNA–protein cross-links and generate double strand breaks, the most deleterious form of DNA damage.

Genetic effects of oxidative DNA damages: comparative mutagenesis of the imidazole ring-opened formamidopyrimidines (Fapy lesions) and 8-oxo-purines in simian kidney cells

Fapy·dG and 8-oxo-7,8-dihydro-2′-deoxyguanosine (8-oxo-dG) are formed in DNA by hydroxyl radical damage. In order to study replication past these lesions in cells, we constructed a single-stranded shuttle vector containing the lesion in 5′-TGT and 5′-TGA sequence contexts. Replication of the modified vector in simian kidney (COS-7) cells showed that Fapy·dG is mutagenic inducing primarily targeted Fapy·G→T transversions. In the 5′-TGT sequence mutational frequency of Fapy·dG was ∼30%, whereas in the 5′-TGA sequence it was ∼8%. In parallel studies 8-oxo-dG was found to be slightly less mutagenic than Fapy·dG, though it also exhibited a similar context effect: 4-fold G→T transversions (24% versus 6%) occurred in the 5′-TGT sequence relative to 5′-TGA. To investigate a possible structural basis for the higher G→T mutations induced by both lesions when their 3′ neighbor was T, we carried out a molecular modeling investigation in the active site of DNA polymerase β, which is known to incorporate both dCTP (no mutation) and dATP (G→T substitution) opposite 8-oxo-G. In pol β, the syn-8-oxo-G:dATP pair showed greater stacking with the 3′-T:A base pair in the 5′-TGT sequence compared with the 3′-A:T in the 5′-TGA sequence, whereas stacking for the anti-8-oxo-G:dCTP pair was similar in both 5′-TGT and 5′-TGA sequences. Similarly, syn-Fapy·G:dATP pairing showed greater stacking in the 5′-TGT sequence compared with the 5′-TGA sequence, while stacking for anti-Fapy·G:dCTP pairs was similar in the two sequences. Thus, for both lesions less efficient base stacking between the lesion:dATP pair and the 3′-A:T base pair in the 5′-TGA sequence might cause lower G→T mutational frequencies in the 5′-TGA sequence compared to 5′-TGT. The corresponding lesions derived from 2′-deoxyadenosine, Fapy·dA and 8-oxo-dA, were not detectably mutagenic in the 5′-TAT sequence, and were only weakly mutagenic (<1%) in the 5′-TAA sequence context, where both lesions induced targeted A→C transversions. To our knowledge this is the first investigation using extrachromosomal probes containing a Fapy·dG or Fapy·dA site-specifically incorporated, which showed unequivocally that in simian kidney cells Fapy·G→T substitutions occur at a higher frequency than 8-oxo-G→T and that Fapy·dA is very weakly mutagenic, as is 8-oxo-dA.

Biologically relevant oxidants and terminology, classification and nomenclature of oxidatively generated damage to nucleobases and 2-deoxyribose in nucleic acids.

Abstract A broad scientific community is involved in investigations aimed at delineating the mechanisms of formation and cellular processing of oxidatively generated damage to nucleic acids. Perhaps as a consequence of this breadth of research expertise, there are nomenclature problems for several of the oxidized bases including 8-oxo-7,8-dihydroguanine (8-oxoGua), a ubiquitous marker of almost every type of oxidative stress in cells. Efforts to standardize the nomenclature and abbreviations of the main DNA degradation products that arise from oxidative pathways are reported. Information is also provided on the main oxidative radicals, non-radical oxygen species, one-electron agents and enzymes involved in DNA degradation pathways as well in their targets and reactivity. A brief classification of oxidatively generated damage to DNA that may involve single modifications, tandem base modifications, intrastrand and interstrand cross-links together with DNA-protein cross-links and base adducts arising from the addition of lipid peroxides breakdown products is also included.

Elucidating DNA damage and repair processes by independently generating reactive and metastable intermediates.

DNA damage is a double-edged sword. The modifications produced in the biopolymer are associated with aging, and give rise to a variety of diseases, including cancer. DNA is also the target of anti-tumor agents and the most generally used nonsurgical treatment of cancer, ionizing radiation. Agents that damage DNA produce a variety of radicals. Elucidating the chemistry of individual DNA radicals is challenging due to the availability of multiple reactive pathways and complexities inherent with carrying out mechanistic studies on a heterogeneous polymer. The ability to independently generate radicals and their metastable products at defined sites in DNA has greatly facilitated understanding this biologically important chemistry.

Radical and radical ion reactivity in nucleic acid chemistry

Preface to Series vii Introduction ix Contributors xi 1. Theoretical Modeling of Radiation-Induced DNA Damage 1 Anil Kumar and Michael D. Sevilla 2. Radical Reaction Pathways Initiated by Direct Energy Deposition in DNA by Ionizing Radiation 41 William A. Bernhard 3. Chemical Reactions of the Radical Cations of Nucleobases in Isolated and Cellular DNA. Formation of Single-Base Lesions 69 Jean Cadet, Thierry Douki, Didier Gasparutto, Jean-Luc Ravanat, and J. Richard Wagner 4. Reactivity of Nucleic Acid Sugar Radicals 99 Chryssostomos Chatgilialoglu 5. Pyrimidine Nucleobase Radical Reactivity 135 Marc M. Greenberg 6. Reactivity of 5-Halopyrimidines in Nucleic Acids 163 Ryu Tashiro and Hiroshi Sugiyama 7. Kinetics of Long-Range Oxidative Electron Transfer Through DNA 191 Kiyohiko Kawai and Tetsuro Majima 8. Radical Intermediates During Reductive Electron Transfer Through DNA 211 Reji Varghese and Hans-Achim Wagenknecht 9. Low-Energy Electron Interaction with DNA: Bond Dissociation and Formation of Transient Anions, Radicals, and Radical Anions 239 Leon Sanche 10. Electronic-Affinic Radiosensitizers 295 Peter Wardman 11. Reactions of Reactive Nitrogen Species and Carbonate Radical Anions with DNA 325 Vladimir Shafirovich, Conor Crean, and Nicholas E. Geacintov 12. Principles and Applications of Electrochemical Oxidation of Nucleic Acids 357 H. Holden Thorp and Julie M. Sullivan 13. DNA Damage Due to Diradical-Generating Cyclizations 389 Sean M. Kerwin 14. DNA Damage by Phenoxyl Radicals 421 Richard A. Manderville Index 445

Direct strand scission from a nucleobase radical in RNA.

RNA oxidation is important in the etiology of disease and as a tool for studying the structure and folding kinetics of this biopolymer. Nucleobase radicals are the major family of reactive intermediates produced in RNA exposed to diffusible species such as hydroxyl radical. The nucleobase radicals are believed to produce direct strand breaks by abstracting hydrogen atoms from their own and neighboring ribose rings. By independently generating the formal C5 hydrogen atom addition product of uridine in RNA, we provide the first chemical characterization of the pathway for direct strand scission from an RNA nucleobase radical. The process is more efficient under anaerobic conditions. The preference for strand scission in double-stranded RNA over single-stranded RNA suggests that this chemistry may be useful for analyzing the secondary structure of RNA in hydroxyl radical cleavage experiments if they are carried out under anaerobic conditions.

Recommendations for standardized description of and nomenclature concerning oxidatively damaged nucleobases in DNA.

We are very grateful to Dr. Gerry Moss, President, IUPAC Division VIII, for his useful comments in the drafting of this document. M.S.C., S.L., P.M., R.O., K.B., and M.D.E. are partners of ECNIS (Environmental Cancer Risk, Nutrition and Individual Susceptibility), a network of excellence operating within the European Union 6th Framework Program, Priority 5: “Food Quality and Safety” (Contract No 513943). J.C. is a member of EU Network COST Action CM0603 “Free Radical in Chemical Biology (CHEMBIO-RADICAL).