Crystallographic characterization of an exocyclic DNA adduct: 3,N4-etheno-2'-deoxycytidine in the dodecamer 5'-CGCGAATTepsilonCGCG-3'

Etheno adducts: from tRNA modifications to DNA adducts and back to miscoding ribonucleotides

Etheno (and ethano) derivatives of nucleic acid bases have an extra 5-membered ring attached. These were first noted as wyosine bases in tRNAs. Some were fluorescent, and the development of etheno derivatives of adenosine, cytosine, and guanosine led to the synthesis of fluorescent analogs of ATP, NAD+, and other cofactors for use in biochemical studies. Early studies with the carcinogen vinyl chloride revealed that these modified bases were being formed in DNA and RNA and might be responsible for mutations and cancer. The etheno bases are also derived from other carcinogenic vinyl monomers. Further work showed that endogenous etheno DNA adducts were present in animals and humans and are derived from lipid peroxidation. The chemical mechanisms of etheno adduct formation involve reactions with bis-electrophiles generated by cytochrome P450 enzymes or lipid peroxidation, which have been established in isotopic labeling studies. The mechanisms by which etheno DNA adducts miscode have been studied with several DNA polymerases, aided by the X-ray crystal structures of these polymerases in mispairing situations and in extension beyond mispairs. Repair of etheno DNA adduct damage is done primarily by glycosylases and also by the direct action of dioxygenases. Some human DNA polymerases (η, κ) can insert bases opposite etheno adducts in DNA and RNA, and the reverse transcriptase activity may be of relevance with the RNA etheno adducts. Further questions involve the extent that the etheno adducts contribute to human cancer.

Base pairing and miscoding properties of 1,N(6)-ethenoadenine- and 3,N(4)-ethenocytosine-containing RNA oligonucleotides

Two RNA phosphoramidites containing the bases 1,N(6)-ethenoadenine (εA) and 3,N(4)-ethenocytosine (εC) were synthesized. These building blocks were incorporated into two 12-mer oligoribonucleotides for evaluation of the base pairing properties of these base lesions by UV melting curve (Tm) and circular dichroism measurements. The Tm data of the resulting duplexes with the etheno modifications opposing all natural bases showed a substantial destabilization compared to the corresponding natural duplexes, confirming their inability to form base pairs. The coding properties of these lesions were further investigated by introducing them into 31-mer oligonucleotides and assessing their ability to serve as templates in primer extension reactions with HIV, AMV, and MMLV reverse transcriptases (RT). Primer extension reactions showed complete arrest of the incorporation process using MMLV RT and AMV RT, while HIV RT preferentially incorporates dAMP opposite εA and dAMP as well as dTMP opposite εC. The properties of these RNA lesions are discussed in the context of its putative biological role.

Structure determination of DNA methylation lesions N1-meA and N3-meC in duplex DNA using a cross-linked protein-DNA system

N(1)-meA and N(3)-meC are cytotoxic DNA base methylation lesions that can accumulate in the genomes of various organisms in the presence of S(N)2 type methylating agents. We report here the structural characterization of these base lesions in duplex DNA using a cross-linked protein-DNA crystallization system. The crystal structure of N(1)-meA:T pair shows an unambiguous Hoogsteen base pair with a syn conformation adopted by N(1)-meA, which exhibits significant changes in the opening, roll and twist angles as compared to the normal A:T base pair. Unlike N(1)-meA, N(3)-meC does not establish any interaction with the opposite G, but remains partially intrahelical. Also, structurally characterized is the N(6)-meA base modification that forms a normal base pair with the opposite T in duplex DNA. Structural characterization of these base methylation modifications provides molecular level information on how they affect the overall structure of duplex DNA. In addition, the base pairs containing N(1)-meA or N(3)-meC do not share any specific characteristic properties except that both lesions create thermodynamically unstable regions in a duplex DNA, a property that may be explored by the repair proteins to locate these lesions.

Structure of the 1,N2-etheno-2'-deoxyguanosine adduct in duplex DNA at pH 8.6

The structure of the 1,N(2)-etheno-2'-deoxyguanosine (1,N(2)-epsilondG) adduct, arising from the reaction of vinyl chloride with dG, was determined in the oligonucleotide duplex 5'-d(CGCATXGAATCC)-3'.5'-d(GGATTCCATGCG)-3' (X=1,N(2)-epsilondG) at pH 8.6 using high resolution NMR spectroscopy. The exocyclic lesion prevented Watson-Crick base-pairing capability at the adduct site and resulted in an approximately 17 degrees C decrease in Tm of the oligodeoxynucleotide duplex. At neutral pH, conformational exchange resulted in spectral line broadening near the adducted site, and it was not possible to determine the structure. However, at pH 8.6, it was possible to obtain well-resolved (1)H NMR spectra. This enabled a total of 385 NOE-based distance restraints to be obtained, consisting of 245 intra- and 140 inter-nucleotide distances. The (31)P NMR spectra exhibited two downfield-shifted resonances, suggesting a localized perturbation of the DNA backbone. The two downfield (31)P resonances were assigned to G(7) and C(19). The solution structure was refined by molecular dynamics calculations restrained by NMR-derived distance and dihedral angle restraints, using a simulated annealing protocol. The generalized Born approximation was used to simulate solvent. The emergent structures indicated that the 1,N(2)-epsilondG-induced structural perturbation was localized at the X(6).C(19) base pair, and its 5'-neighbor T(5).A(20). Both 1,N(2)-epsilondG and the complementary dC adopted the anti conformation about the glycosyl bonds. The 1,N (2)-epsilondG adduct was inserted into the duplex but was shifted towards the minor groove as compared to dG in a normal Watson-Crick C.G base pair. The complementary cytosine was displaced toward the major groove. The 5'-neighbor T(5).A(20) base pair was destabilized with respect to Watson-Crick base pairing. The refined structure predicted a bend in the helical axis associated with the adduct site.

Substrate specificity of human thymine-DNA glycosylase on exocyclic cytosine adducts

The environmental carcinogen glycidaldehyde (GDA) and therapeutic chloroethylnitrosoureas (CNUs) can form hydroxymethyl etheno and ring-saturated ethano bases, respectively. The mutagenic potential of these adducts relies on their miscoding properties and repair efficiency. In this work, the ability of human thymine-DNA glycosylase (TDG) to excise 8-(hydroxymethyl)-3,N(4)-ethenocytosine (8-hm-varepsilonC) and 3,N(4)-ethanocytosine (EC) was investigated and compared with varepsilonC, a known substrate for TDG. When tested using defined oligonucleotides containing a single adduct, TDG is able to excise 8-hm-varepsilonC but not EC. The 8-hm-varepsilonC activity mainly depends on guanine pairing with the adduct. TDG removes 8-hm-varepsilonC less efficiently than varepsilonC but its activity can be significantly enhanced by human AP endonuclease 1 (APE1), a downstream enzyme in the base excision repair. TDG did not show any detectable activity toward EC when placed in various neighboring sequences, including the 5'-CpG site. Molecular modeling revealed a possible steric clash between the non-planar EC exocyclic ring and residue Asn 191 within the TDG active site, which could account for the lack of TDG activity toward EC. TDG was not active against the bulkier exocyclic adduct 3,N(4)-benzethenocytosine, nor the two adenine derivatives with same modifications as the cytosine derivatives, 7-hm-varepsilonA and EA. These findings expand the TDG substrate range and aid in understanding the structural requirements for TDG substrate specificity.

Nucleic acid crystallography: current progress

Fifty years after the publication of the DNA double helix model by Watson and Crick, new nucleic acid structures keep emerging at an ever-increasing rate. The past three years have brought a flurry of new oligonucleotide structures, including those of a Hoogsteen-paired DNA duplex, Holliday junctions, DNA-drug complexes, quadruplexes, a host of RNA motifs and various nucleic acid analogues. Major advances were also made in terms of the structure and function of catalytic RNAs. These range from improved models of the phosphodiester cleavage reactions catalyzed by the hairpin and hepatitis delta virus ribozymes to the visualization of a complete active site of a group I self-splicing intron with bound 5'- and 3'-exons. These triumphs are complemented by a refined understanding of cation-nucleic-acid interactions and new routes to the generation of derivatives for phasing of DNA and RNA structures.

Chloroethylnitrosourea-derived ethano cytosine and adenine adducts are substrates for Escherichia coli glycosylases excising analogous etheno adducts

Exocyclic ethano DNA adducts are saturated etheno ring derivatives formed mainly by therapeutic chloroethylnitrosoureas (CNUs), which are also mutagenic and carcinogenic. In this work, we report that two of the ethano adducts, 3,N4-ethanocytosine (EC) and 1,N6-ethanoadenine (EA), are novel substrates for the Escherichia coli mismatch-specific uracil-DNA glycosylase (Mug) and 3-methyladenine DNA glycosylase II (AlkA), respectively. It has been shown previously that Mug excises 3,N4-ethenocytosine (epsilonC) and AlkA releases 1,N6-ethenoadenine (epsilonA). Using synthetic oligonucleotides containing a single ethano or etheno adduct, we found that both glycosylases had a approximately 20-fold lower excision activity toward EC or EA than that toward their structurally analogous epsilonC or epsilonA adduct. Both enzymes were capable of excising the ethano base paired with any of the four natural bases, but with varying efficiencies. The Mug activity toward EC could be stimulated by E. coli endonuclease IV and, more efficiently, by exonuclease III. Molecular dynamics (MD) simulations showed similar structural features of the etheno and ethano derivatives when present in DNA duplexes. However, also as shown by MD, the stacking interaction between the EC base and Phe 30 in the Mug active site is reduced as compared to the epsilonC base, which could account for the lower EC activity observed in this study.

Repair of exocyclic DNA adducts: rings of complexity

Exocyclic DNA adducts are mutagenic lesions that can be formed by both exogenous and endogenous mutagens/carcinogens. These adducts are structurally analogs but can differ in certain features such as ring size, conjugation, planarity and substitution. Although the information on the biological role of the repair activities for these adducts is largely unknown, considerable progress has been made on their reaction mechanisms, substrate specificities and kinetic properties that are affected by adduct structures. At least four different mechanisms appear to have evolved for the removal of specific exocyclic adducts. These include base excision repair, nucleotide excision repair, mismatch repair, and AP endonuclease-mediated repair. This overview highlights the recent progress in such areas with emphasis on structure-activity relationships. It is also apparent that more information is needed for a better understanding of the biological and structural implications of exocyclic adducts and their repair.