An abasic site in DNA. Solution conformation determined by proton NMR and molecular mechanics calculations

Structure of a Stable Interstrand DNA Cross-Link Involving a β-N-Glycosyl Linkage Between an N6-dA Amino Group and an Abasic Site

Abasic (AP) sites are one of the most common forms of DNA damage. The deoxyribose ring of AP sites undergoes anomerization between α and β configurations, via an electrophilic aldehyde intermediate. In sequences where an adenine residue is located on the opposing strand and offset 1 nt to the 3' side of the AP site, the nucleophilic N⁶-dA amino group can react with the AP aldehyde residue to form an interstrand cross-link (ICL). Here, we present an experimentally determined structure of the dA-AP ICL by NMR spectroscopy. The ICL was constructed in the oligodeoxynucleotide 5'-d(T¹A²T³G⁴T⁵C⁶T⁷A⁸A⁹G¹⁰T¹¹T¹²C¹³A¹⁴T¹⁵C¹⁶T¹⁷A¹⁸)-3':5'-d(T¹⁹A²⁰G²¹A²²T²³G²⁴A²⁵A²⁶C²⁷X²⁸T²⁹A³⁰G³¹A³²C³³A³⁴T³⁵A³⁶)-3' (X=AP site), with the dA-AP ICL forming between A⁸ and X²⁸. The NMR spectra indicated an ordered structure for the cross-linked DNA duplex and afforded detailed spectroscopic resonance assignments. Structural refinement, using molecular dynamics calculations restrained by NOE data (rMD), revealed the structure of the ICL. In the dA-AP ICL, the 2'-deoxyribosyl ring of the AP site was ring-closed and in the β configuration. Juxtapositioning the N⁶-dA amino group and the aldehydic C1 of the AP site within bonding distance while simultaneously maintaining two flanking unpaired A⁹ and T²⁹ bases stacked within the DNA is accomplished by the unwinding of the DNA at the ICL. The structural data is discussed in the context of recent studies describing the replication-dependent unhooking of the dA-AP ICL by the base excision repair glycosylase NEIL3.

New insights into abasic site repair and tolerance

Thousands of apurinic/apyrimidinic (AP or abasic) sites form in each cell, each day. This simple DNA lesion can have profound consequences to cellular function, genome stability, and disease. As potent blocks to polymerases, they interfere with the reading and copying of the genome. Since they provide no coding information, they are potent sources of mutation. Due to their reactive chemistry, they are intermediates in the formation of lesions that are more challenging to repair including double-strand breaks, interstrand crosslinks, and DNA protein crosslinks. Given their prevalence and deleterious consequences, cells have multiple mechanisms of repairing and tolerating these lesions. While base excision repair of abasic sites in double-strand DNA has been studied for decades, new interest in abasic site processing has come from more recent insights into how they are processed in single-strand DNA. In this review, we discuss the source of abasic sites, their biological consequences, tolerance mechanisms, and how they are repaired in double and single-stranded DNA.

Surface-enhanced Raman spectroscopy (SERS) characterisation of abasic sites in DNA duplexes

Acquisition of the intrinsic SERS spectra of abasic sites containing DNA enables their structural characterisation and discrimination.

Effect of an abasic site on strand slippage in DNA primer-templates

An abasic site is the most common lesion in DNA. It is also an intermediate product formed during base excision repair. Previously, we demonstrated that strand slippage can occur in primer-template model systems containing any kind of natural templating bases, suggesting deletion and expansion errors are possible in any kind of sequences during DNA replication. In this study, nuclear magnetic resonance spectroscopic investigations have been performed to study the intrinsic effect of a templating abasic residue on strand slippage in primer-template models. A DNA hairpin model system containing an abasic site and a 5'-overhang region was used to mimic the situation that a dNTP has just been incorporated opposite the abasic site. Our results show that, after dNTP incorporation, strand slippage occurs regardless of the type of terminal base pair formed. Compared to natural templating bases, abasic sites possess a higher slippage propensity, implicating a higher chance of expansion or deletion errors during DNA replication.

Solvent exposure associated with single abasic sites alters the base sequence dependence of oxidation of guanine in DNA in GG sequence contexts

The effect of exposure of guanine in double-stranded oligonucleotides to aqueous solvent during oxidation by one-electron oxidants was investigated by introducing single synthetic tetrahydrofuran-type abasic sites (Ab) either adjacent to or opposite tandem GG sequences. The selective oxidation of guanine was initiated by photoexcitation of the aromatic sensitizers riboflavin and a pyrene derivative, and by the relatively small negatively charged carbonate radical anion. The relative rates of oxidation of the 5'- and 3' side G in runs of 5'⋅⋅⋅GG⋅⋅⋅ (evaluated by standard hot alkali treatment of the damaged DNA strand followed by high resolution gel electrophoresis of the cleavage fragments) are markedly affected by adjacent abasic sites either on the same or opposite strand. For example, in fully double-stranded DNA or one with an Ab adjacent to the 5'-G, the 5'-G/3'-G damage ratio is ≥4, but is inverted (<1.0) with the Ab adjacent to the 3'-G. These striking effects of Ab are attributed to the preferential localization of the "hole" on the most solvent-exposed guanine regardless of the size, charge, or reduction potential of the oxidizing species.

DNA synthesis across an abasic lesion by yeast REV1 DNA polymerase

Abasic (apurinic/apyrimidinic) sites are among the most abundant DNA lesions in humans, and they present a strong block to replication. They are also highly mutagenic because when replicative DNA polymerases manage to insert a nucleotide opposite the lesion, they prefer to insert an A. Rev1, a member of Y-family DNA polymerases, does not obey the A-rule. This enzyme inserts a C opposite an abasic lesion with much greater catalytic efficiency than an A, G, or T. We present here the structure of yeast Rev1 in ternary complex with DNA containing an abasic lesion and with dCTP as the incoming nucleotide. The structure reveals a mechanism of synthesis across an abasic lesion that differs from that in other polymerases. The lesion is driven to an extrahelical position, and the incorporation of a C is mediated by an arginine (Arg324) that is conserved in all known orthologs of Rev1, including humans. The hydrophobic cavity that normally accommodates the unmodified G is instead filled with water molecules. Since Gs are especially prone to depurination through a spontaneous hydrolysis of the glycosidic bond, the ability of Rev1 to stabilize an abasic lesion in its active site and employ a surrogate arginine to incorporate a C provides a unique means for the "error-free" bypass of this noninstructional lesion.

NMR solution structures of clustered abasic site lesions in DNA: structural differences between 3'-staggered (-3) and 5'-staggered (+3) bistranded lesions

Ionizing radiation produces a distinctive pattern of bistranded clustered lesions in DNA. A relatively low number of clustered lesions may be lethal to cells when compared to a larger number of single lesions. Enzyme cleavage experiments suggest that the orientation of bistranded lesions causes differential recognition and removal of these lesions. Like that of a previous study of bistranded abasic site lesion [Hazel, R. D., Tian, K., and de los Santos, C. (2008) Biochemistry 47, 11909-11919], the aim of this investigation was to determine the structures of two DNA duplexes each containing two synthetic apurinic/apyrimidinic (AP) residues, positioned on opposite strands and separated by two base pairs. In the first duplex, the AP residues are staggered in the 3' orientation [-3 duplex, (AP)(2)-3 duplex], while in the second duplex, the AP residues are staggered in the 5' orientation [+3 duplex, (AP)(2)+3 duplex]. NOESY spectra recorded in 100 and 10% D(2)O buffer solutions allowed the assignment of the nonexchangeable and exchangeable protons, respectively, for each duplex. Cross-peak connectivity in the nonexchangeable proton spectra indicates that the duplex is a regular right-handed helix with the AP residues and orphan bases located inside the duplexes. The exchangeable proton spectra establish the formation of Watson-Crick G·C alignment for the two base pairs between the lesion sites in both duplexes. Distance-restrained molecular dynamics simulation confirmed the intrahelical orientations of the AP residues. The proximity of the AP residues across the minor groove of the -3 duplex and across the major groove in the +3 duplex is similar to their locations in the case of -1 and +1 clusters. This difference in structure may be a key factor in the differential recognition of bistranded AP lesions by human AP endonuclease.

DNA polymerase beta substrate specificity: side chain modulation of the "A-rule"

Apurinic/apyrimidinic (AP) sites are continuously generated in genomic DNA. Left unrepaired, AP sites represent noninstructional premutagenic lesions that are impediments to DNA synthesis. When DNA polymerases encounter an AP site, they generally insert dAMP. This preferential insertion is referred to as the A-rule. Crystallographic structures of DNA polymerase (pol) beta, a family X polymerase, with active site mismatched nascent base pairs indicate that the templating (i.e. coding) base is repositioned outside of the template binding pocket thereby diminishing interactions with the incorrect incoming nucleotide. This effectively produces an abasic site because the template pocket is devoid of an instructional base. However, the template pocket is not empty; an arginine residue (Arg-283) occupies the space vacated by the templating nucleotide. In this study, we analyze the kinetics of pol beta insertion opposite an AP site and show that the preferential incorporation of dAMP is lost with the R283A mutant. The crystallographic structures of pol beta bound to gapped DNA with an AP site analog (tertrahydrofuran) in the gap (binary complex) and with an incoming nonhydrolyzable dATP analog (ternary complex) were solved. These structures reveal that binding of the dATP analog induces a closed polymerase conformation, an unstable primer terminus, and an upstream shift of the templating residue even in the absence of a template base. Thus, dATP insertion opposite an abasic site and dATP misinsertions have common features.

DNA synthesis across an abasic lesion by human DNA polymerase iota

Abasic sites are among the most abundant DNA lesions formed in human cells, and they present a strong block to replication. DNA polymerase iota (Poliota) is one of the few DNA Pols that does not follow the A-rule opposite an abasic site. We present here three structures of human Poliota in complex with DNAs containing an abasic lesion and dGTP, dTTP, or dATP as the incoming nucleotide. The structures reveal a mechanism of translesion synthesis across an abasic lesion that differs from that in other Pols. Both the abasic lesion and the incoming dNTPs are intrahelical and are closely apposed across a constricted active site cleft. The dNTPs partake in distinct networks of hydrogen bonds in the "void" opposite the lesion. These different patterns of hydrogen bonds, as well as stacking interactions, may underlie Poliota's small preference for insertion of dGTP over other nucleotides opposite this common lesion.

Mutational specificity and genetic control of replicative bypass of an abasic site in yeast

Abasic (AP) sites represent one of the most frequently formed lesions in DNA, and they present a strong block to continued synthesis by the replicative DNA polymerases (Pols). Here we determine the mutational specificity and the genetic control of translesion synthesis (TLS) opposite an AP site in yeast by using a double-stranded plasmid system that we have devised in which bidirectional replication proceeds from a replication origin. We find that the rate, the genetic control, and the types and frequencies of nucleotides inserted opposite the AP site are very similar for both the leading and the lagging DNA strands, and that an A is predominantly inserted opposite the AP site, whereas C insertion by Rev1 constitutes a much less frequent event. In striking contrast, in studies that have been reported previously for AP bypass with gapped-duplex and single-stranded plasmids, it has been shown that a C is the predominant nucleotide inserted opposite the AP site. We discuss the implications of our observations for the mechanisms of TLS on the leading versus the lagging DNA strand and suggest that lesion bypass during replication involves the coordination of activities of the replicative Pol with that of the lesion-bypass Pol.

Quantification of DNA BI/BII backbone states in solution. Implications for DNA overall structure and recognition

The backbone states of B-DNA influence its helical parameters, groove dimensions, and overall curvature. Therefore, detection and fine characterization of these conformational states are desirable. Using routine NMR experiments on a nonlabeled B-DNA oligomer and analyzing high-resolution X-ray structures, we investigated the relationship between interproton distances and backbone conformational states. The three H2'i-H6/8i+1, H2' 'i-H6/8i+1, and H6/8i-H6/8i+1 sequential distances were found cross-correlated and linearly coupled to epsilon-zeta values in X-ray structures and 31P chemical shifts (deltaP) in NMR that reflect the interconversion between the backbone BI (epsilon-zeta < 0 degrees ) and BII (epsilon-zeta > 0 degrees) states. These relationships provide a detailed check of the NMR data consistency and the possibility to extend the set of restraints for structural refinement through various extrapolations. Furthermore, they allow translation of deltaP in terms of BI/BII ratios. Also, comparison of many published deltaP in solution to crystal data shows that the impact of sequence on the BI/BII propensities is similar in both environments and is therefore an intrinsic and general property of B-DNA. This quantification of the populations of BI and BII is of general interest because these sequence-dependent backbone states act on DNA overall structure, a key feature for DNA-protein-specific recognition.

NMR assessment of the global shape of a non-labelled DNA dodecamer containing a tandem of G-T mismatches

We have carried out a solution study of two non-labelled self-complementary DNA dodecamers d(GACTGTACAGTC)2 and d(GACTGTGCAGTC)2 by NMR, the second sequence composed of two G-T mismatches. Structures were determined using distances extracted from NOE effects alone or using both NOE and RDC constraints, measured in three different liquid crystalline media. We ensured that our data on the influence of the mesogen on the DNA structures, and the way in which the RDCs were incorporated as constraints in the protocol refinement, were consistent. We also tested the influence of different sets of RDCs and the best means of optimizing the calculation of D(a) and R. Resolution and accuracy of the ten best energy final structures were compared. The addition of a small set of RDC constraints significantly improves the final determined structures. We took advantage of the specificity of the RDC, i.e. it contains orientational information, and explored the global shape of the DNA duplexes; it was found that the duplexes do not have a large curvature. For the G-T base pair, we observed, in this particular sequence (tandem of G-T mismatches), a new pattern of base pairing, which involved the formation of a bifurcated hydrogen bond.

Crystallographic snapshots of a replicative DNA polymerase encountering an abasic site

Abasic sites are common DNA lesions, which are strong blocks to replicative polymerases and are potentially mutagenic when bypassed. We report here the 2.8 A structure of the bacteriophage RB69 replicative DNA polymerase attempting to process an abasic site analog. Four different complexes were captured in the crystal asymmetric unit: two have DNA in the polymerase active site whereas the other two molecules are in the exonuclease mode. When compared to complexes with undamaged DNA, the DNA surrounding the abasic site reveals distinct changes suggesting why the lesion is so poorly bypassed: the DNA in the polymerase active site has not translocated and is therefore stalled, precluding extension. All four molecules exhibit conformations that differ from the previously published structures. The polymerase incorporates dAMP across the lesion under crystallization conditions, indicating that the different conformations observed in the crystal may be part of the active site switching reaction pathway.

Requirement of Watson-Crick hydrogen bonding for DNA synthesis by yeast DNA polymerase eta

Classical high-fidelity DNA polymerases discriminate between the correct and incorrect nucleotides by using geometric constraints imposed by the tight fit of the active site with the incipient base pair. Consequently, Watson-Crick (W-C) hydrogen bonding between the bases is not required for the efficiency and accuracy of DNA synthesis by these polymerases. DNA polymerase eta (Poleta) is a low-fidelity enzyme able to replicate through DNA lesions. Using difluorotoluene, a nonpolar isosteric analog of thymine unable to form W-C hydrogen bonds with adenine, we found that the efficiency and accuracy of nucleotide incorporation by Poleta are severely impaired. From these observations, we suggest that W-C hydrogen bonding is required for DNA synthesis by Poleta; in this regard, Poleta differs strikingly from classical high-fidelity DNA polymerases.

Integrity of duplex structures without hydrogen bonding: DNA with pyrene paired at abasic sites

DNA polymerases specifically insert the hydrophobic pyrene deoxynucleotide (P) opposite tetrahydrofuran (F), an stable abasic site analog, and DNA duplexes containing this non-hydrogen-bonded pair possess a high degree of thermodynamic stability. These observations support the hypothesis that steric complementarity and stacking interactions may be sufficient for maintaining stability of DNA structure and specificity of DNA replication, even in the absence of hydrogen bonds across the base pair. Here we report the NMR characterization and structure determination of two DNA molecules containing pyrene residues. The first is a 13mer duplex with a pyrene.tetrahydrofuran pair (P.F pair) at the ninth position and the second mimics a replication intermediate right after incorporation of a pyrene nucleoside opposite an abasic site. Our data indicate that both molecules adopt right-handed helical conformations with Watson- Crick alignments for all canonical base pairs. The pyrene ring stays inside the helix close to its baseless partner in both molecules. The single-stranded region of the replication intermediate folds back over the opposing strand, sheltering the hydrophobic pyrene moiety from water exposure. The results support the idea that the stability and replication of a P.F pair is due to its ability to mimic Watson-Crick structure.

Yeast Rev1 protein is a G template-specific DNA polymerase

Rev1 protein of Saccharomyces cerevisiae functions with DNA polymerase zeta in mutagenic trans-lesion synthesis. Because of the reported preferential incorporation of a C residue opposite an abasic site, Rev1 has been referred to as a deoxycytidyltransferase. Here, we use steady-state kinetics to examine nucleotide incorporation by Rev1 opposite undamaged and damaged template residues. We show that Rev1 specifically inserts a C residue opposite template G, and it is approximately 25-, 40-, and 400-fold less efficient at inserting a C residue opposite an abasic site, an O(6)-methylguanine, and an 8-oxoguanine lesion, respectively. Rev1 misincorporates G, A, and T residues opposite template G with a frequency of approximately 10(-3) to 10(-4). Consistent with this finding, Rev1 replicates DNA containing a string of Gs in a template-specific manner, but it has a low processivity incorporating 1.6 nucleotides per DNA binding event on the average. From these observations, we infer that Rev1 is a G template-specific DNA polymerase.

The solution structure of an oligonucleotide duplex containing a 2'-deoxyadenosine-3-(2-hydroxyethyl)- 2'-deoxyuridine base pair determined by NMR and molecular dynamics studies

Determination of the solution structure of the duplex d(GCAAGTC(HE)AAAACG)*d(CGTTTTAGACTTGC) containing a 3-(2-hydroxyethyl)-2'-deoxyuridine*deoxyadenine (HE*A) base pair is reported. The three-dimensional solution structure, determined starting from 512 models via restrained molecular mechanics using inter-proton distances and torsion angles, converged to two final families of structures. For both families the HE and the opposite A residues are intrahelical and in the anti conformation. The hydroxyethyl chain lies close to the helix axis and for one family the hydroxyl group is above the HE*A plane and in the other case it is below. These two models were used to start molecular dynamic calculations with explicit solvent to explore the hydrogen bonding possibilities of the HE*A base pair. The dynamics calculations converge finally to one model structure in which two hydrogen bonds are formed. The first is formed all the time and is between HEO4 and the amino group of A, and the second, an intermittent one, is between the hydroxyl group and the N1 of A. When this second hydrogen bond is not formed a weak interaction CH...N is possible between HEC7H2 and N1A21. All the best structures show an increase in the C1'-C1' distance relative to a Watson-Crick base pair.

1H NMR studies of a 17-mer DNA duplex

Transcription factor 1 (TF1), encoded by the Bacillus subtilis bacteriophage SPO1, is a DNA-binding protein of the HU family. In preparation for a determination of the structure of the DNA-TF1 complex, we have studied the conformation of one core 17-mer duplex d(5'-CACTACTCTTTGTAGTG-3')-d(5'-CACTACAAAGAGTAGTG-3'). NOESY, DQF-COSY and TOCSY spectroscopy provide resonance assignments of non-exchangeable and exchangeable protons, internucleotide and interstrand proton-proton distances, and dihedral angle constraints. Restrained molecular dynamics calculations yield a family of NMR solution structures for which the RMSD is 0.7 A (all atoms). The helical twist is 34.9 degrees for the central 15 bp. Bends toward the major groove are located between the second and fourth base pairs from each end. The G12 x C23 base pair, which is bounded on each side by consecutive A x T pairs, causes a local disturbance to the DNA helix that makes the conformations of the two end segments unsymmetrical. The pyrimidine rings at T9, T10 and T11 experience more extensive rotational movement than the rest of the structure.

Solution structure of an oligonucleotide containing an abasic site: evidence for an unusual deoxyribose conformation

The antitumor antibiotic bleomycin causes two major lesions in the deoxyribose backbone of DNA: formation of 4'-keto abasic sites and formation of strand breaks with 3'-phosphoglycolate and 5'-phosphate ends. As a model for the 4'-keto abasic site, we have characterized an abasic site (X) in d(CCAAAGXACTGGG).d(CCCAGTACTTTGG) by two-dimensional NMR spectroscopy. A total of 475 NOEs and 101 dihedral angles provided the restraints for molecular modeling. Four unusual NOEs were observed between each anomer of the abasic site and the neighboring bases. In addition, four coupling constants for adjacent protons of the deoxyribose of both the alpha and beta anomers of the abasic site were observed. The modeling suggests that for both anomers the abasic site is extrahelical, without significant distortion of the backbone opposite the lesion. The coupling constants further allowed assignment of an unusual sugar pucker for each anomer. The unique position of the abasic site in our structural model for each anomer is discussed in terms of repair of such lesions in vivo.

The major human abasic endonuclease: formation, consequences and repair of abasic lesions in DNA

DNA continuously suffers the loss of its constituent bases, and thereby, a loss of potentially vital genetic information. Sites of missing bases--termed abasic or apurinic/apyrimidinic (AP) sites--form spontaneously, through damage-induced hydrolytic base release, or by enzyme-catalyzed removal of modified or mismatched bases during base excision repair (BER). In this review, we discuss the structural and biological consequences of abasic lesions in DNA, as well as the multiple repair pathways for such damage, while emphasizing the mechanistic operation of the multi-functional human abasic endonuclease APE1 (or REF-1) and its potential relationship to disease.

NMR characterization of clustered bistrand abasic site lesions: effect of orientation on their solution structure

A unique characteristic of ionizing radiation and radiomimetic anticancer drugs is the induction of clustered damage: two or more DNA lesions (oxidized bases, abasic sites, or strand breaks) occurring in the same or different strands of the DNA molecule within a single turn of the helix. In spite of arising at a lower frequency than single lesions, clustered DNA damage represents an exotic challenge to the repair systems present in the cells and, in some cases, these lesions may escape detection and/or processing. To understand the structural properties of clustered DNA lesions we have prepared two oligodeoxynucleotide duplexes containing adjacent tetrahydrofuran residues (abasic site analogues), positioned one in each strand of the duplex in a 5' or 3' orientation, and determined their solution structure by NMR spectroscopy and molecular dynamics simulations. The NMR data indicate that both duplex structures are right-handed helices of high similarity outside the clustered damage site. The thermal stability of the duplexes is severely reduced by the presence of the abasic residues, especially in a 5' orientation where the melting temperature is 5 degrees C lower. The structures show remarkable differences at the lesion site where the extrahelical location of the tetrahydrofuran residues in the (AP)(2)-5'-staggered duplex contrasts with their smooth alignment along the sugar-phosphate backbone in the (AP)(2)-3'-staggered duplex.

Roles of yeast DNA polymerases delta and zeta and of Rev1 in the bypass of abasic sites

Abasic (AP) sites are one of the most frequently formed lesions in DNA, and they present a strong block to continued synthesis by the replicative DNA machinery. Here we show efficient bypass of an AP site by the combined action of yeast DNA polymerases delta and zeta. In this reaction, Poldelta inserts an A nucleotide opposite the AP site, and Polzeta subsequently extends from the inserted nucleotide. Consistent with these observations, sequence analyses of mutations in the yeast CAN1s gene indicate that A is the nucleotide inserted most often opposite AP sites. The nucleotides C, G, and T are also incorporated, but much less frequently. Enzymes such as Rev1 and Poleta may contribute to the insertion of these other nucleotides; the predominant role of Rev1 in AP bypass, however, is likely to be structural. Steady-state kinetic analyses show that Polzeta is highly inefficient in incorporating nucleotides opposite the AP site, but it efficiently extends from nucleotides, particularly an A, inserted opposite this lesion. Thus, in eukaryotes, bypass of an AP site requires the sequential action of two DNA polymerases, wherein the extension step depends solely upon Polzeta, but the insertion step can be quite varied, involving not only the predominant action of the replicative DNA polymerase, Poldelta, but also the less prominent role of various translesion synthesis polymerases.

Solution conformation of an RNA--DNA hybrid duplex containing a pyrimidine RNA strand and a purine DNA strand

RNA--DNA hybrid duplexes are involved in transcription, replication and reverse transcription of nucleic acids. Information on such duplexes may shed some light on the mechanism of these processes. For this purpose, the influence of base composition on the structure of a polypyrimidine--polypurine RNA--DNA duplex r(cucuccuucucuu). d(GAGAGGAAGAGAA) has been studied using 1H, 31P and 13C NMR experiments, molecular modeling (JUMNA program) and NOE back-calculation methods. The resulting structure of the 13-mer hybrid duplex shows that the RNA strand is in the expected A-type conformation while the DNA strand is in a very flexible conformation. In the DNA strand, the desoxyribose sugars retain the C2'-endo B-type conformation. The duplex helical parameters (such as inclination, twist and displacement of the bases) are close to the A-type conformation. No bending was observed for the global axis curvature. The major groove width is close to the B-form value and the minor groove width is intermediate between standard values for A and B-forms. These results are in favour of the independence of minor groove size (where RNase H interacts) and the base composition of the hybrid duplexes.

Inefficient bypass of an abasic site by DNA polymerase eta

DNA polymerase eta (Pol eta) bypasses a cis-syn thymine-thymine dimer efficiently and accurately, and inactivation of Pol eta in humans results in the cancer-prone syndrome, the variant form of xeroderma pigmentosum. Also, Pol eta bypasses the 8-oxoguanine lesion efficiently by predominantly inserting a C opposite this lesion, and it bypasses the O(6)-methylguanine lesion by inserting a C or a T. To further assess the range of DNA lesions tolerated by Pol eta, here we examine the bypass of an abasic site, a prototypical noninstructional lesion. Steady-state kinetic analyses show that both yeast and human Pol eta are very inefficient in both inserting a nucleotide opposite an abasic site and in extending from the nucleotide inserted. Hence, Pol eta bypasses this lesion extremely poorly. These results suggest that Pol eta requires the presence of template bases opposite both the incoming nucleotide and the primer terminus to catalyze efficient nucleotide incorporation.

Abasic DNA structure, reactivity, and recognition

Loss of a base in DNA, i.e., creation of an abasic site leaving a deoxyribose residue in the strand, is a frequent lesion that may occur spontaneously, or under the action of radiations and alkylating agents, or enzymatically as an intermediate in the repair of modified or abnormal bases. The abasic site lesion is mutagenic or lethal if not repaired. From a chemical point of view,the abasic site is an alkali-labile residue that leads to strand breakage through beta- and delta- elimination. Progress in the understanding of the chemistry and enzymology of abasic DNA largely relies upon the study of synthetic abasic duplexes. Several efficient synthetic methods have thus been developed to introduce the lesion (or a stable analogue) at defined position in the sequence. Physicochemical and spectroscopic examination of such duplexes, including calorimetry, melting temperature, high-field nmr and molecular modeling indicate that the lesion strongly destabilizes the duplex, although remaining in the canonical B-form with structural modifications strictly located at the site of the lesion. Probes have been developed to titrate the damage in DNA in vitro. Series of molecules have been devised to recognize specifically the abasic site, exhibiting a cleavage activity and mimicking the AP nucleases. Others have been prepared that bind strongly to the abasic site and show promise in potentiating the cytotoxic and antitumor activity of the clinically used nitrosourea (bis-chloroethylnitrosurea).

Oligodeoxynucleotides containing conformationally constrained abasic sites: a UV and fluorescence spectroscopic investigation on duplex stability and structure

The synthesis and incorporation into oligodeoxy-nucleotides of two novel, conformationally restricted abasic (AB) site analogs are described. The stability of oligonucleotide 18mer duplexes containing one such AB site opposite any of the four natural DNA bases was investigated by UV melting curve analysis and compared to that of duplexes containing a conformationally flexible propanediol unit 1 or a tetrahydrofuran unit 2 as an AB site analog. No major differences in the melting temperatures (DeltaT(m) 0-3 degrees C) between the different abasic duplexes were observed. All AB duplexes were found to have T(m)s that were lower by 9-15 degrees C relative to a fully matched 18mer control duplex, and by 4-10 degrees C relative to the corresponding 19mer duplexes in which the AB site is replaced by a mismatched nucleobase. Thus we conclude that the loss of stability of a duplex that is encountered by removal of a nucleobase from the stack cannot be compensated with conformational restriction of the AB site. From the van't Hoff transition enthalpies obtained from the melting curves, it appears that melting cooperativity is higher for the duplexes containing the conformationally rigid AB sites. Fluorescence quenching experiments with duplexes containing the fluorescent base 2-amino-purine (2AP) opposite the AB sites showed a weak tendency towards more efficient stacking of this base in duplexes containing the conformationally constrained AB sites. Thus, such AB sites may structurally stabilize the cavity formed by the removal of a base. Potential applications emerging from the properties of such conformationally constrained AB sites in DNA diagnostics are discussed.

DNA damage-induced mutation: tolerance via translesion synthesis

Translesion synthesis (TLS) appears to be required for most damage-induced mutagenesis in the yeast Saccharomyces cerevisiae, whether the damage arises from endogenous or exogenous sources. Thus, the production of such mutations seems to occur primarily as a consequence of the tolerance of DNA lesions rather than an error-prone repair mechanism. Tolerance via TLS in yeast involves proteins encoded by members of the RAD6 epistasis group for the repair of ultraviolet (UV) photoproducts, in particular two non-essential DNA polymerases that catalyse error-free or error-prone TLS. Homologues of these RAD6 group proteins have recently been discovered in rodent and/or human cells. Furthermore, the operation of error-free TLS in humans has been linked to a reduced risk of UV-induced skin cancer, whereas mutations generated by error-prone TLS may increase the risk of cancer. In this article, we review and link the evidence for translesion synthesis in yeast, and the involvement of nonreplicative DNA polymerases, to recent findings in mammalian cells.

Replication of non-hydrogen bonded bases by DNA polymerases: a mechanism for steric matching

Recent experiments have presented evidence that Watson-Crick hydrogen bonds in a base pair are not absolute requirements for efficient synthesis of that pair by DNA polymerase enzymes. Here we examine quantitative steady-state kinetic data from several published studies involving poorly hydrogen-bonding DNA base analogues and adducts, and analyze the results in terms of solvation, hydrogen bonding, and steric effects. We propose a mechanism that can explain the surprising lack of hydrogen-bonding requirement accompanied by significant selectivity in pairing. This hypothesis makes use of steric matching, enforced both by the tightly confined polymerase active site and by the DNA backbone, as a chief factor determining nucleotide selection during DNA synthesis. The results also suggest that hydrogen bonds from bases to water (solvation) may be important in increasing the effective size of DNA bases, which may help prevent misinsertion of small bases opposite each other.

The Dewar photoproduct of thymidylyl(3'-->5')- thymidine (Dewar product) exhibits mutagenic behavior in accordance with the "A rule"

In contrast to the highly mutagenic pyrimidine(6-4)pyrimidone photoproduct, its Dewar valence isomer (Dewar product) has low mutagenic potential and produces a broad range of mutations [LeClerc, J. E., Borden, A. & Lawrence, C. W. (1991) Proc. Natl. Acad. Sci. USA 88, 9685-9689]. To determine the origin of the mutagenic property of the Dewar product, we used experimental NMR restraints and molecular dynamics to determine the solution structure of a Dewar-lesion DNA decamer duplex. This DNA decamer duplex (DW/GA duplex) contains a mismatched base pair between the 3' T residue of the Dewar lesion (T6) and an opposed G residue (G15). The 3' T (T6) of the Dewar lesion formed stable hydrogen bonds with the opposing G15 residue. However, the helical bending and unwinding angles of the DW/GA duplex were much larger than those of a second duplex that contains the Dewar lesion and opposing A15 and A16 residues (DW/AA duplex). The DW/GA duplex showed poorer stacking interactions at the two bases of the Dewar product and at the adjacent A7 small middle dotT14 base pair than did the DW/AA duplex. These structural features imply that no thermal stability or conformational benefit is obtained by incorporating a G instead of an A opposite the 3' T of the Dewar lesion. These properties may thus facilitate the preferential incorporation of an A in accordance with the A rule during translesion replication and lead to the low frequency of 3' T-->C mutations observed at this site.

The impact of abasic sites on DNA flexibility

We use internal coordinate molecular mechanics calculations to study the impact of abasic sites on the conformation and the mechanics of the DNA double helix. Abasic sites, which are common mutagenic lesions, are shown to locally modify both the groove geometry and the curvature of DNA in a sequence dependent manner. By controlled twisting and bending, it is also shown that these lesions modify the deformability of the duplex, generally increasing its flexibility, but again to an extent which depends on the nature of the abasic site and on the surrounding base sequence. Both the conformational and mechanical influence of this type of DNA damage may be significant for recognition and repair mechanisms.

Abasic sites in duplex DNA: molecular modeling of sequence-dependent effects on conformation

Molecular modeling calculations using JUnction Minimization of Nucleic Acids (JUMNA) have been used to study sequence effects on the conformation of abasic sites within duplex DNA. We have considered lesions leading to all possible unpaired bases (X), adenine, guanine, cytosine, or thymine contained within two distinct sequence contexts, CXC and GXG. Calculations were carried out on DNA 11-mers using extensive conformational search techniques to locate the most stable abasic conformations and using Poisson-Boltzmann corrected electrostatics to account for solvation effects. The results, which are in very good agreement with available experimental data, point to strong sequence effects on both the position of the unpaired base (intra or extrahelical) and on the overall curvature induced by the abasic lesion. For CXC, unpaired purines are found to lie within the helix, while unpaired pyrimidines are either extrahelical or in equilibrium between the intra and extrahelical forms. For GXG, all unpaired bases lead to intrahelical forms, but with marked, sequence-dependent differences in induced curvature.

NMR-derived solution structure of a 17mer hydroxymethyluracil-containing DNA

Incorporation of 5-(hydroxymethyl)-2'-deoxyuridine into DNA in place of thymine by SPO1, a Bacillus subtilis bacteriophage, allows the viral DNA to bind selectively to transcription factor 1. We have synthesized a TF1-binding site: d(5'-ACCHACHCHHHGHAGGT-3')-d(5'-ACCHACAAAGAGHAGGT-3') and studied this molecule using NMR spectroscopy. The chemical shifts of exchangeable and non-exchangeable protons were sequentially assigned. Absence of corresponding NOEs in the imino-imino region suggested that the end base pairs did not form Watson-Crick hydrogen bond. Restrained molecular dynamics calculation yielded a family of B-DNA structures whose r.m.s.d. was 0.66 A (all atoms) for the internal 15 bp. The helical twist was 38.5 degrees per step. The base pairs were situated directly on the helix axis (X-displacement = -0.2 A). All sugars exhibited C2'-endo puckering with P = 167.3 degrees and upsilon(max)= 38.2 degrees. The OH groups of all hmU bases resided on the 3' side of the base plane and may affect the base orientation relative to the sugar plane as the average chi value for all hmU was 4 degrees more positive than that of other nucleosides (258 degrees versus 254 degrees ). Positive roll angles (rho) and small flanking twists (omega) at hmU suggested that the two hmU-A base pair steps open toward the minor grooves.

Cytosine arabinoside lesions are position-specific topoisomerase II poisons and stimulate DNA cleavage mediated by the human type II enzymes

Cytosine arabinoside (araC) is an important drug used for the treatment of human leukemias. In order to exert its cytotoxic effects, araC must be incorporated into chromosomal DNA. Although specific DNA lesions that involve base loss or modification stimulate nucleic acid cleavage mediated by type II topoisomerases, the effects of deoxyribose sugar ring modification on enzyme activity have not been examined. Therefore, the effects of incorporated araC residues on the DNA cleavage/religation equilibrium of human topoisomerase IIalpha and beta were characterized. AraC lesions were position-specific topoisomerase II poisons and stimulated DNA scission mediated by both human type II enzymes. However, the positional specificity of araC residues differed from that previously reported for other cleavage-enhancing DNA lesions. Finally, additive or synergistic increases in DNA cleavage were observed in the presence of araC lesions and etoposide. These findings broaden the range of DNA lesions known to alter topoisomerase II function and raise the possibility that this enzyme may mediate some of the cellular effects of araC.

Experimental and theoretical studies of the conformational perturbations induced by an abasic site

The three-dimensional structure of the natural undecamer duplex d(CGCACACACGC). d(GCGTGTGTGCG) has been determined by the combined use of NMR spectroscopy and restrained molecular dynamics (rMD) and also by molecular mechanics calculations using the JUMNA program without experimental distance constraints. Both procedures have also been used to model the abasic structure d(CGCACOCACGC).d(GCGTGTGTGCG), where 'O' indicates a modified abasic site: 3-hydroxy-2-(hydroxymethyl) tetrahydrofuran. For the natural duplex, 134 interproton distances have been obtained by complete relaxation matrix analysis of the NOESY cross-peaks intensities, using MARDIGRAS software. These distances along with 100 torsion angles for sugar ring and additional data derived from canonical A and B-DNA, have been used for structures refinement by restrained molecular dynamics. Comparison of the natural oligomer with the abasic structure obtained earlier by NMR/rMD (Y. Coppel, N. Berthet, C. Coulombeau, Ce. Coulombeau, J. Garcia and J. Lhomme, Biochemistry 36, 4817-4830, 1997) confirms that the creation of an abasic site, in this sequence context, leads to marked helix kinking. It is also shown that the JUMNA procedure is capable of reproducing the overall structural features of the natural and damaged DNA conformations without the use of experimental constraints.

AP site structural determinants for Fpg specific recognition

The binding of Escherichia coli and Lactococcus lactis Fapy-DNA glyosylase (Fpg) proteins to DNA containing either cyclic or non-cyclic abasic (AP) site analogs was investigated by electrophoretic mobility shift assay (EMSA) and by footprinting experiments. We showed that the reduced AP site is the best substrate analog for the E.coli and L.lactis enzymes ( K Dapp = 0.26 and 0.5 nM, respectively) as compared with the other analogs tested in this study ( K Dapp >2.8 nM). The 1,3-propanediol (Pr) residue-containing DNA seems to be the minimal AP site structure allowing a Fpg specific DNA binding, since the ethyleneglycol residue is not specifically bound by these enzymes. The newly described cyclopentanol residue is better recognized than tetrahydrofuran (for the E.coli Fpg, K Dapp = 2.9 and 25 nM, respectively). These results suggest that the hemiacetal form of the AP site is negatively discriminated by the Fpg protein suggesting a hydrogen bond between the C4'-hydroxyl group of the sugar and a Fpg residue. High-resolution hydroxyl radical footprinting using a duplex containing Pr shows that Fpg binds to six nucleotides on the strand containing the AP site and only the base opposite the lesion on the undamaged complementary strand. This comparative study provides new information about the molecular mechanism involved in the Fpg AP lyase activity.

Heterogeneous repair of N-methylpurines at the nucleotide level in normal human cells

Base excision repair rates of dimethyl sulfate-induced 3-methyladenine and 7-methylguanine adducts were measured at nucleotide resolution along the PGK1 gene in normal human fibroblasts. Rates of 7-methylguanine repair showed a 30-fold dependence on nucleotide position, while position-dependent repair rates of 3-methyladenine varied only sixfold. Slow excision rates for 7-methylguanine bases afforded the opportunity to study their excision in vitro as a model for base excision repair. A two-component in vitro excision system, composed of human N-methylpurine-DNA glycosylase (MPG protein) and dimethyl sulfate-damaged DNA manifested sequence context-dependent rate differences for 7-methylguanine of up to 185-fold from position to position. This in vitro system reproduced both the global repair rate, and for the PGK1 coding region, the position-dependent repair patterns observed in cells. The equivalence of in vivo repair and in vitro excision data indicates that removal of 7-methylguanine by the MPG protein is the rate-limiting step in base excision repair of this lesion. DNA "repair rate footprints" associated with DNA glycosylase accessibility were observed only in a region with bound transcription factors. The "repair rate footprints" represent a rare chromatin component of 7-meG base excision repair otherwise dominated by sequence-context dependence. Comparison of in vivo repair rates to in vitro rates for 3-methyladenine, however, shows that the rate-limiting step determining position-dependent repair for this adduct is at one of the post-DNA glycosylase stages. In conclusion, this study demonstrates that a comparison of sequence context-dependent in vitro reaction rates to in vivo position-dependent repair rates permits the identification of steps responsible for position-dependent repair. Such analysis is now feasible for the different steps and adducts repaired via the base excision repair pathway.

2-Aminopurine fluorescence studies of base stacking interactions at abasic sites in DNA: metal-ion and base sequence effects

Metal-ion and sequence dependent changes in the stacking interactions of bases surrounding abasic (AB) sites in 10 different DNA duplexes were examined by incorporating the fluorescent nucleotide probe 2-aminopurine (2-AP), opposite to the site (AB-APopp) or adjacent to the site (AB-APadj) on either strand. A detailed study of the fluorescence emission and excitation spectra of these AB duplexes and their corresponding parent duplexes indicates that AB-APoppis significantly less stacked than 2-AP in the corresponding normal duplex. In general, AB-APadjon the AB strand is stacked, but AB-APadjon the opposite strand shows destabilized stacking interactions. The results also indicate that divalent cation binding to the AB duplexes contributes to destabilizaton of the base stacking interactions of AB-APopp, but has little or no effect on the stacking interactions of AB-APadj. Consistent with these results, the fluorescence of AB-APoppis 18-30-fold more sensitive to an externally added quenching agent than the parent normal duplex. When uracil DNA glycosylase binds to AB-APoppin the presence of 2.5 mM MgCl2, a 3-fold decrease in fluorescence is observed ( K d = 400 +/- 90 nM) indicating that the unstacked 2-APoppbecomes more stacked upon binding. On the basis of these fluorescence studies a model for the local base stacking interactions at these AB sites is proposed.

Structure of a DNA base-excision product resembling a cisplatin inter-strand adduct

Base-excision of a self-complementary oligonucleotide with central G:T mismatches by the G:T/U-specific mismatch DNA glycosylase (MUG), generates an unusual DNA structure which is remarkably similar in conformation to an interstrand DNA adduct of the anti-tumor drug cis-diamminedichloroplatinum. The abasic sugars generated by excision of the mismatched thymines are extruded from the double-helix, and the 'widowed' deoxyguanosines rotate so that their N7 and O6 groups protrude into the minor groove of the duplex and restack in an interleaved intercalative geometry, generating a kink in the helix axis.

Structures of apurinic and apyrimidinic sites in duplex DNAs

Natural and exogenous processes can give rise to abasic sites with either a purine or pyrimidine as the base on the opposing strand. The solution state structures of the apyrimidinic DNA duplex, with D6 indicating an abasic site, [sequence: see text] referred to as AD, and the apurinic DNA duplex with a dC17, referred to as CD, have been determined. A particularly striking difference is that the abasic site in CD is predominantly a beta hemiacetal, whereas in AD the alpha and beta forms are equally present. Hydrogen bonding with water by the abasic site and the base on the opposite strand appears to play a large role in determining the structure near the damaged site. Comparison of these structures with that of a duplex DNA containing a thymine glycol at the same position as the abasic site and with that of a duplex DNA containing an abasic site in the middle of a curved DNA sequence offers some insight into the common and distinct structural features of damaged DNA sites.

Solution structure of duplex DNA containing an extrahelical abasic site analog determined by NMR spectroscopy and molecular dynamics

Translesional DNA synthesis past abasic sites proceeds with the preferential incorporation of dAMP opposite the lesion and, depending on the sequence context, one or two base deletions. High-resolution NMR spectroscopy and molecular dynamics simulations were used to determine the three-dimensional structure of a DNA heteroduplex containing a synthetic abasic site (tetrahydrofuran) residue positioned in a sequence that promotes one base deletions. Analysis of NMR spectra indicates that the stem region of the duplex adopts a right-handed helical structure and the glycosidic torsion angle is in anti orientation for all residues. NOE interactions establish Watson-Crick alignments for all canonical base pairs of the duplex. Measurement of distance interactions at the lesion site shows the abasic residue excluded from the helix. Restrained molecular dynamics simulations generated three-dimensional models in excellent agreement with the spectroscopic data. These structures show a regular duplex region and a slight bend at the lesion site. The tetrahydrofuran residue extrudes from the helix and is highly flexible. The model reported here, in conjunction with a previous study performed on abasic sites, explains the structural bias of one-base deletion mutations.

Structure of oligonucleotides with either a strand break or a bulged nucleotide

We report NMR and molecular modelling studies on a DNA duplex structure which is composed of three oligonucleotides and mimics a strand break. Although it retains a B form conformation our model suggests that it is kinked at the strand break. In the same sequence with an extra bulged adenosine at the centre for the major species this residue is stacked in the helix and a kink is observed in the model.

Solution structure as a function of pH of two central mismatches, C . T and C . C, in the 29 to 39 K-ras gene sequence, by nuclear magnetic resonance and molecular dynamics

The DNA duplexes 5' d(GCCACCAGCTC) x d(GAGCTXGTGGC), where the base X is either cytosine or thymine, have been studied by one and two-dimensional nuclear magnetic resonance, energy minimization and molecular dynamics. The sequence studied corresponds to the region 29 to 39 of the K-ras gene and is a hot spot for mutations. The results show that both duplexes adopt a globally B-DNA-type structure. For the C x C mismatch, we observe a structural change as a function of pH with an apparent pK of 6.95. The neutral species has only one hydrogen bond between the two bases but shows two families of wobble structures where one base or the other is displaced in the major groove. The protonated species has two hydrogen bonds and two structures but of unequal populations. In both systems, the sugar puckers remain predominantly C2'-endo and no significant changes in the backbone structure are observed. The neutral C . T mismatch is stabilized by two hydrogen bonds but, surprisingly, it can also be protonated, although the apparent pK is much lower, 5.65. In this case, protonation does not result in an additional hydrogen bond but must be due to better base-stacking interactions for C+ x T. The NMR data show that the environment of the T imino proton is very similar for C x T and C+ x T, although the hydrogen bond acceptor would be expected to be a nitrogen atom in the former case and an oxygen atom in the latter. We propose that for both structures there is an intervening water molecule which in addition reduces backbone strain. We have also measured the fluctuations during molecular dynamics runs in these mismatches. All are greater than for Watson-Crick base-pairs and the C x C mismatch shows very pronounced mobility.

Abasic translesion synthesis by DNA polymerase beta violates the "A-rule". Novel types of nucleotide incorporation by human DNA polymerase beta at an abasic lesion in different sequence contexts

The "A-rule" reflects the preferred incorporation of dAMP opposite abasic lesions in Escherichia coli in vivo. DNA polymerases (pol) from procaryotic and eucaryotic organisms incorporate nucleotides opposite abasic lesions in accordance with the A-rule. However, recent in vivo data demonstrate that A is not preferentially incorporated opposite abasic lesions in eucaryotes. Purified human DNA polymerases beta and alpha are used to measure the specificity of nucleotide incorporation at a site-directed tetrahydrofuran abasic lesion, in 8-sequence contexts, varying upstream and downstream bases adjacent to the lesion. Extension past the lesion is measured in 4 sequence contexts, varying the downstream template base. Pol alpha strongly favors incorporation of dAMP directly opposite the lesion. In marked contrast, pol beta violates the A-rule for incorporation directly opposite the lesion. In addition to incorporation taking place directly opposite the lesion, we also analyze misalignment incorporation directed by a template base downstream from the lesion. Lesion bypass by pol beta occurs predominantly by "skipping over" the lesion, by insertion of a nucleotide complementary to an adjacent downstream template site. Misalignment incorporation for pol beta occurs by a novel "dNTP-stabilized" mechanism resulting in both deletion and base substitution errors. In contrast, pol alpha shows no propensity for this type of synthesis. The misaligned DNA structures generated during dNTP-stabilized lesion bypass do not conform to misaligned structures reported previously.