Structures of apurinic and apyrimidinic sites in duplex DNAs

Intrinsic Strand-Incision Activity of Human UNG: Implications for Nick Generation in Immunoglobulin Gene Diversification

Uracil arises in cellular DNA by cytosine (C) deamination and erroneous replicative incorporation of deoxyuridine monophosphate opposite adenine. The former generates C → thymine transition mutations if uracil is not removed by uracil-DNA glycosylase (UDG) and replaced by C by the base excision repair (BER) pathway. The primary human UDG is hUNG. During immunoglobulin gene diversification in activated B cells, targeted cytosine deamination by activation-induced cytidine deaminase followed by uracil excision by hUNG is important for class switch recombination (CSR) and somatic hypermutation by providing the substrate for DNA double-strand breaks and mutagenesis, respectively. However, considerable uncertainty remains regarding the mechanisms leading to DNA incision following uracil excision: based on the general BER scheme, apurinic/apyrimidinic (AP) endonuclease (APE1 and/or APE2) is believed to generate the strand break by incising the AP site generated by hUNG. We report here that hUNG may incise the DNA backbone subsequent to uracil excision resulting in a 3´-α,β-unsaturated aldehyde designated uracil-DNA incision product (UIP), and a 5´-phosphate. The formation of UIP accords with an elimination (E2) reaction where deprotonation of C2´ occurs via the formation of a C1´ enolate intermediate. UIP is removed from the 3´-end by hAPE1. This shows that the first two steps in uracil BER can be performed by hUNG, which might explain the significant residual CSR activity in cells deficient in APE1 and APE2.

Mass Spectrometry of Nucleic Acid Noncovalent Complexes

Nucleic acids have been among the first targets for antitumor drugs and antibiotics. With the unveiling of new biological roles in regulation of gene expression, specific DNA and RNA structures have become very attractive targets, especially when the corresponding proteins are undruggable. Biophysical assays to assess target structure as well as ligand binding stoichiometry, affinity, specificity, and binding modes are part of the drug development process. Mass spectrometry offers unique advantages as a biophysical method owing to its ability to distinguish each stoichiometry present in a mixture. In addition, advanced mass spectrometry approaches (reactive probing, fragmentation techniques, ion mobility spectrometry, ion spectroscopy) provide more detailed information on the complexes. Here, we review the fundamentals of mass spectrometry and all its particularities when studying noncovalent nucleic acid structures, and then review what has been learned thanks to mass spectrometry on nucleic acid structures, self-assemblies (e.g., duplexes or G-quadruplexes), and their complexes with ligands.

Complementary Functions of Plant AP Endonucleases and AP Lyases during DNA Repair of Abasic Sites Arising from C:G Base Pairs

Abasic (apurinic/apyrimidinic, AP) sites are ubiquitous DNA lesions arising from spontaneous base loss and excision of damaged bases. They may be processed either by AP endonucleases or AP lyases, but the relative roles of these two classes of enzymes are not well understood. We hypothesized that endonucleases and lyases may be differentially influenced by the sequence surrounding the AP site and/or the identity of the orphan base. To test this idea, we analysed the activity of plant and human AP endonucleases and AP lyases on DNA substrates containing an abasic site opposite either G or C in different sequence contexts. AP sites opposite G are common intermediates during the repair of deaminated cytosines, whereas AP sites opposite C frequently arise from oxidized guanines. We found that the major Arabidopsis AP endonuclease (ARP) exhibited a higher efficiency on AP sites opposite G. In contrast, the main plant AP lyase (FPG) showed a greater preference for AP sites opposite C. The major human AP endonuclease (APE1) preferred G as the orphan base, but only in some sequence contexts. We propose that plant AP endonucleases and AP lyases play complementary DNA repair functions on abasic sites arising at C:G pairs, neutralizing the potential mutagenic consequences of C deamination and G oxidation, respectively.

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.

The Rad51 paralogs facilitate a novel DNA strand specific damage tolerance pathway

Accurate DNA replication is essential for genomic stability and cancer prevention. Homologous recombination is important for high-fidelity DNA damage tolerance during replication. How the homologous recombination machinery is recruited to replication intermediates is unknown. Here, we provide evidence that a Rad51 paralog-containing complex, the budding yeast Shu complex, directly recognizes and enables tolerance of predominantly lagging strand abasic sites. We show that the Shu complex becomes chromatin associated when cells accumulate abasic sites during S phase. We also demonstrate that purified recombinant Shu complex recognizes an abasic analog on a double-flap substrate, which prevents AP endonuclease activity and endonuclease-induced double-strand break formation. Shu complex DNA binding mutants are sensitive to methyl methanesulfonate, are not chromatin enriched, and exhibit increased mutation rates. We propose a role for the Shu complex in recognizing abasic sites at replication intermediates, where it recruits the homologous recombination machinery to mediate strand specific damage tolerance.

The homologous recombination machinery needs to be recruited at replication intermediates for accurate functioning. Here, the authors reveal that a Rad51 paralog-containing complex, called the Shu complex, recognizes and enables tolerance of predominantly lagging strand abasic sites.

Nonenzymatic release of N7-methylguanine channels repair of abasic sites into an AP endonuclease-independent pathway in Arabidopsis

Abasic (apurinic/apyrimidinic, AP) sites in DNA arise from spontaneous base loss or by enzymatic removal during base excision repair. It is commonly accepted that both classes of AP site have analogous biochemical properties and are equivalent substrates for AP endonucleases and AP lyases, although the relative roles of these two types of enzymes are not well understood. We provide here genetic and biochemical evidence that, in Arabidopsis, AP sites generated by spontaneous loss of N7-methylguanine (N7-meG) are exclusively repaired through an AP endonuclease-independent pathway initiated by FPG, a bifunctional DNA glycosylase with AP lyase activity. Abasic site incision catalyzed by FPG generates a single-nucleotide gap with a 3'-phosphate terminus that is processed by the DNA 3'-phosphatase ZDP before repair is completed. We further show that the major AP endonuclease in Arabidopsis (ARP) incises AP sites generated by enzymatic N7-meG excision but, unexpectedly, not those resulting from spontaneous N7-meG loss. These findings, which reveal previously undetected differences between products of enzymatic and nonenzymatic base release, may shed light on the evolution and biological roles of AP endonucleases and AP lyases.

How abasic sites impact hole transfer dynamics in GC-rich DNA sequences

Hole transfer dynamics through GC-rich DNA duplexes containing abasic sites is strongly modulated by the nature of the unpaired nucleobase.

Thymine DNA glycosylase exhibits negligible affinity for nucleobases that it removes from DNA

Thymine DNA Glycosylase (TDG) performs essential functions in maintaining genetic integrity and epigenetic regulation. Initiating base excision repair, TDG removes thymine from mutagenic G·T mispairs caused by 5-methylcytosine (mC) deamination and other lesions including uracil (U) and 5-hydroxymethyluracil (hmU). In DNA demethylation, TDG excises 5-formylcytosine (fC) and 5-carboxylcytosine (caC), which are generated from mC by Tet (ten–eleven translocation) enzymes. Using improved crystallization conditions, we solved high-resolution (up to 1.45 Å) structures of TDG enzyme–product complexes generated from substrates including G·U, G·T, G·hmU, G·fC and G·caC. The structures reveal many new features, including key water-mediated enzyme–substrate interactions. Together with nuclear magnetic resonance experiments, the structures demonstrate that TDG releases the excised base from its tight product complex with abasic DNA, contrary to previous reports. Moreover, DNA-free TDG exhibits no significant binding to free nucleobases (U, T, hmU), indicating a K_d >> 10 mM. The structures reveal a solvent-filled channel to the active site, which might facilitate dissociation of the excised base and enable caC excision, which involves solvent-mediated acid catalysis. Dissociation of the excised base allows TDG to bind the beta rather than the alpha anomer of the abasic sugar, which might stabilize the enzyme–product complex.

Analysis of structural flexibility of damaged DNA using thiol-tethered oligonucleotide duplexes

Bent structures are formed in DNA by the binding of small molecules or proteins. We developed a chemical method to detect bent DNA structures. Oligonucleotide duplexes in which two mercaptoalkyl groups were attached to the positions facing each other across the major groove were prepared. When the duplex contained the cisplatin adduct, which was proved to induce static helix bending, interstrand disulfide bond formation under an oxygen atmosphere was detected by HPLC analyses, but not in the non-adducted duplex, when the two thiol-tethered nucleosides were separated by six base pairs. When the insert was five and seven base pairs, the disulfide bond was formed and was not formed, respectively, regardless of the cisplatin adduct formation. The same reaction was observed in the duplexes containing an abasic site analog and the (6-4) photoproduct. Compared with the cisplatin case, the disulfide bond formation was slower in these duplexes, but the reaction rate was nearly independent of the linker length. These results indicate that dynamic structural changes of the abasic site- and (6-4) photoproduct-containing duplexes could be detected by our method. It is strongly suggested that the UV-damaged DNA-binding protein, which specifically binds these duplexes and functions at the first step of global-genome nucleotide excision repair, recognizes the easily bendable nature of damaged DNA.

Loss of loop adenines alters human telomere d[AG3(TTAG3)3] quadruplex folding

Abasic (AP) lesions are the most frequent type of damages occurring in cellular DNA. Here we describe the conformational effects of AP sites substituted for 2′-deoxyadenosine in the first (ap7), second (ap13) or third (ap19) loop of the quadruplex formed in K⁺ by the human telomere DNA 5′-d[AG₃(TTAG₃)₃]. CD spectra and electrophoresis reveal that the presence of AP sites does not hinder the formation of intramolecular quadruplexes. NMR spectra show that the structural heterogeneity is substantially reduced in ap7 and ap19 as compared to that in the wild-type. These two (ap7 and ap19) sequences are shown to adopt the hybrid-1 and hybrid-2 quadruplex topology, respectively, with AP site located in a propeller-like loop. All three studied sequences transform easily into parallel quadruplex in dehydrating ethanol solution. Thus, the AP site in any loop region facilitates the formation of the propeller loop. Substitution of all adenines by AP sites stabilizes the parallel quadruplex even in the absence of ethanol. Whereas guanines are the major determinants of quadruplex stability, the presence or absence of loop adenines substantially influences quadruplex folding. The naturally occurring adenine-lacking sites in the human telomere DNA can change the quadruplex topology in vivo with potentially vital biological consequences.

Structure and dynamics of DNA duplexes containing a cluster of mutagenic 8-oxoguanine and abasic site lesions

Clustered DNA damage sites are caused by ionizing radiation. They are much more difficult to repair than are isolated single lesions, and their biological outcomes in terms of mutagenesis and repair inhibition are strongly dependent on the type, relative position and orientation of the lesions present in the cluster. To determine whether these effects on repair mechanism could be due to local structural properties within DNA, we used (1)H NMR spectroscopy and restrained molecular dynamics simulation to elucidate the structures of three DNA duplexes containing bistranded clusters of lesions. Each DNA sequence contained an abasic site in the middle of one strand and differed by the relative position of the 8-oxoguanine, staggered on either the 3' or the 5' side of the complementary strand. Their repair by base excision repair protein Fpg was either complete or inhibited. All the studied damaged DNA duplexes adopt an overall B-form conformation and the damaged residues remain intrahelical. No striking deformations of the DNA chain have been observed as a result of close proximity of the lesions. These results rule out the possibility that differential recognition of clustered DNA lesions by the Fpg protein could be due to changes in the DNA's structural features induced by those lesions and provide new insight into the Fpg recognition process.

On the formation and properties of interstrand DNA-DNA cross-links forged by reaction of an abasic site with the opposing guanine residue of 5'-CAp sequences in duplex DNA

We recently reported that the aldehyde residue of an abasic (Ap) site in duplex DNA can generate an interstrand cross-link via reaction with a guanine residue on the opposing strand. This finding is intriguing because the highly deleterious nature of interstrand cross-links suggests that even small amounts of Ap-derived cross-links could make a significant contribution to the biological consequences stemming from the generation of Ap sites in cellular DNA. Incubation of 21-bp duplexes containing a central 5'-CAp sequence under conditions of reductive amination (NaCNBH(3), pH 5.2) generated much higher yields of cross-linked DNA than reported previously. At pH 7, in the absence of reducing agents, these Ap-containing duplexes also produced cross-linked duplexes that were readily detected on denaturing polyacrylamide gels. Cross-link formation was not highly sensitive to reaction conditions, and the cross-link, once formed, was stable to a variety of workup conditions. Results of multiple experiments including MALDI-TOF mass spectrometry, gel mobility, methoxyamine capping of the Ap aldehyde, inosine-for-guanine replacement, hydroxyl radical footprinting, and LC-MS/MS were consistent with a cross-linking mechanism involving reversible reaction of the Ap aldehyde residue with the N(2)-amino group of the opposing guanine residue in 5'-CAp sequences to generate hemiaminal, imine, or cyclic hemiaminal cross-links (7-10) that were irreversibly converted under conditions of reductive amination (NaCNBH(3)/pH 5.2) to a stable amine linkage. Further support for the importance of the exocyclic N(2)-amino group in this reaction was provided by an experiment showing that installation of a 2-aminopurine-thymine base pair at the cross-linking site produced high yields (15-30%) of a cross-linked duplex at neutral pH, in the absence of NaCNBH(3).

Chemistry and structural biology of DNA damage and biological consequences

The formation of adducts by the reaction of chemicals with DNA is a critical step for the initiation of carcinogenesis. The structural analysis of various DNA adducts reveals that conformational and chemical rearrangements and interconversions are a common theme. Conformational changes are modulated both by the nature of adduct and the base sequences neighboring the lesion sites. Equilibria between conformational states may modulate both DNA repair and error-prone replication past these adducts. Likewise, chemical rearrangements of initially formed DNA adducts are also modulated both by the nature of adducts and the base sequences neighboring the lesion sites. In this review, we focus on DNA damage caused by a number of environmental and endogenous agents, and biological consequences.

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.

NMR solution structures of bistranded abasic site lesions in DNA

Ionizing radiation produces clustered lesions in DNA. Since the orientation of bistranded lesions affects their recognition by DNA repair enzymes, clustered damages are more difficult to process and thus more toxic than single oxidative lesions. In order to understand the structural determinants that lead to differential recognition, we used NMR spectroscopy and restrained molecular dynamics to solve the structure of two DNA duplexes, each containing two stable abasic site analogues positioned on opposite strands of the duplex and staggered in the 3' (-1 duplex, (AP) 2-1 duplex) or 5' (+1 duplex, (AP) 2+1 duplex) direction. Cross-peak connectivities observed in the nonexchangeable NOESY spectra indicate compression of the helix at the lesion site of the duplexes, resulting in the formation of two abasic bulges. The exchangeable proton spectra show the AP site partner nucleotides forming interstrand hydrogen bonds that are characteristic of a Watson-Crick G.C base pairs, confirming the extra helical nature of the AP residues. Restrained molecular dynamics simulations generate a set of converging structures in full agreement with the spectroscopic data. In the (AP) 2-1 duplex, the extra helical abasic site residues reside in the minor groove of the helix, while they appear in the major groove in the (AP) 2+1 duplex. These structural differences are consistent with the differential recognition of bistranded abasic site lesions by human AP endonuclease.

Structures and energetics of base flipping of the thymine dimer depend on DNA sequence

The cis,syn-cyclobutane pyrimidine dimer (CPD) is a photoinduced DNA lesion leading to a significant distortion of the DNA structure. Its repair by DNA photolyase requires a flip of the damaged base into an extrahelical position. This base flip is expected to be sequence-dependent, but the structures and energetics as a function of the bases 3' and 5' to the CPD lesion are unknown. Eight-nanosecond MD simulations of four different hexadecamer duplexes with the CPD were performed for the flipped-in and flipped-out structures. Analysis of these results indicates clear sequence-dependent differences. Significant disruptions of the base pairs to the 3' side of the CPD are observed for the flipped-out structures with adjacent A-T pairs, whereas those with G-C pairs adjacent show no such distortions. The conformational spaces occupied by these two duplexes are significantly different. The structural differences correlate well with the free energy differences for base flipping calculated using the previously established 2D potential of mean force (PMF) method. The energy differences for base flipping in duplexes containing A, T, G, and C pairs adjacent to the CPD were found to be 6.25-6.5, 5.25-5.5, 7.25-7.5, and 6.5-6.75 kcal/mol, respectively. These energy differences of up to 2 kcal/mol should be large enough to be detected experimentally using sensitive probes.

Tumors established with cell lines selected for oxaliplatin resistance respond to oxaliplatin if combined with cetuximab

PURPOSE

To establish whether cetuximab, a chimeric IgG1 antibody targeting epidermal growth factor receptor, has the potential to restore responsiveness to oxaliplatin in preclinical cancer models, as has been shown with irinotecan in irinotecan refractory metastatic colorectal cancer patients.

EXPERIMENTAL DESIGN

The effects of cetuximab and oxaliplatin, alone or in combination, were tested in vitro and in vivo using human colorectal cancer cell lines selected for oxaliplatin resistance, as well as parental control cell lines. Evaluations were made of subcutaneous xenograft tumor growth in nu/nu athymic mice, as well as activation of mitogen-activated protein kinase (extracellular signal-regulated kinase 1/2) and AKT, expression of DNA repair genes, density of apurinic/apyrimidinic DNA damage, and accumulation of platinum-DNA adducts in vitro.

RESULTS

Oxaliplatin + cetuximab efficacy in murine subcutaneous xenograft models was greater than that of monotherapies and independent of the responsiveness to oxaliplatin monotherapy. In vitro, cetuximab reduced expression of excision repair cross-complementation group 1 and XPF, which are key components of the nucleotide excision repair pathway involved in the excision of platinum-DNA adducts. In addition, cetuximab reduced expression of XRCC1, a component of the base excision repair pathway responsible for the repair of apurinic/apyrimidinic sites. Effects of cetuximab on DNA repair protein levels were downstream to effects on mitogen-activated protein kinase and AKT pathway activation. In line with effects on DNA repair protein expression, cetuximab increased the accumulation of platinum and apurinic/apyrimidinic sites on DNA during oxaliplatin treatment.

CONCLUSIONS

Cetuximab has the potential to salvage the benefits of oxaliplatin in oxaliplatin-resistant colorectal cancer patients by reducing DNA repair capacity.

Sequence dependence in base flipping: experimental and computational studies

Base flipping is the movement of a DNA base from an intrahelical, base-stacked position to an extrahelical, solvent-exposed position. As there are favorable interactions for an intrahelical base, both hydrogen bonding and base stacking, base flipping is expected to be energetically prohibitive for an undamaged DNA duplex. For damaged DNA bases, however, the energetic cost of base flipping may be considerably lower. Using a selective, non-covalent assay for base flipping, the sequence dependence of base flipping in DNA sequences containing an abasic site has been studied. The dissociation constants of the zinc-cyclen complex to small molecules and single strands of DNA as well as the equilibrium constants for base flipping have been determined for these sequences. Molecular dynamics simulations of the zinc-cyclen complex bound to both single- and double-stranded DNA have been performed in an attempt to rationalize the differences in the dissociation constants obtained for the two systems. The results are compared to previous studies of base flipping in DNA containing an abasic site.

DNA oligonucleotides with A, T, G or C opposite an abasic site: structure and dynamics

Abasic sites are common DNA lesions resulting from spontaneous depurination and excision of damaged nucleobases by DNA repair enzymes. However, the influence of the local sequence context on the structure of the abasic site and ultimately, its recognition and repair, remains elusive. In the present study, duplex DNAs with three different bases (G, C or T) opposite an abasic site have been synthesized in the same sequence context (5′-CCA AAG₆ XA₈C CGG G-3′, where X denotes the abasic site) and characterized by 2D NMR spectroscopy. Studies on a duplex DNA with an A opposite the abasic site in the same sequence has recently been reported [Chen,J., Dupradeau,F.-Y., Case,D.A., Turner,C.J. and Stubbe,J. (2007) Nuclear magnetic resonance structural studies and molecular modeling of duplex DNA containing normal and 4′-oxidized abasic sites. Biochemistry, 46, 3096–3107]. Molecular modeling based on NMR-derived distance and dihedral angle restraints and molecular dynamics calculations have been applied to determine structural models and conformational flexibility of each duplex. The results indicate that all four duplexes adopt an overall B-form conformation with each unpaired base stacked between adjacent bases intrahelically. The conformation around the abasic site is more perturbed when the base opposite to the lesion is a pyrimidine (C or T) than a purine (G or A). In both the former cases, the neighboring base pairs (G6-C21 and A8-T19) are closer to each other than those in B-form DNA. Molecular dynamics simulations reveal that transient H-bond interactions between the unpaired pyrimidine (C20 or T20) and the base 3′ to the abasic site play an important role in perturbing the local conformation. These results provide structural insight into the dynamics of abasic sites that are intrinsically modulated by the bases opposite the abasic site.

Mechanism of abasic lesion bypass catalyzed by a Y-family DNA polymerase

The 3 million-base pair genome of Sulfolobus solfataricus likely undergoes depurination/depyrimidination frequently in vivo. These unrepaired abasic lesions are expected to be bypassed by Dpo4, the only Y-family DNA polymerase from S. solfataricus. Interestingly, these error-prone Y-family enzymes have been shown to be physiologically vital in reducing the potentially negative consequences of DNA damage while paradoxically promoting carcinogenesis. Here we used Dpo4 as a model Y-family polymerase to establish the mechanistic basis for DNA lesion bypass. While showing efficient bypass, Dpo4 paused when incorporating nucleotides directly opposite and one position downstream from an abasic lesion because of a drop of several orders of magnitude in catalytic efficiency. Moreover, in disagreement with a previous structural report, Dpo4-catalyzed abasic bypass involves robust competition between the A-rule and the lesion loop-out mechanism and is governed by the local DNA sequence. Analysis of the strong pause sites revealed biphasic kinetics for incorporation indicating that Dpo4 primarily formed a nonproductive complex with DNA that converted slowly to a productive complex. These strong pause sites are mutational hot spots with the embedded lesion even affecting the efficiency of five to six downstream incorporations. Our results suggest that abasic lesion bypass requires tight regulation to maintain genomic stability.

DNA-duplexes containing abasic sites: correlation between thermostability and acoustic wave properties

Aldehydic apurinic or apyrimidinic sites that lack a nucleobase moiety are one of the most common forms of toxic lesions in DNA. In the present study, a close structural analog of such a site, the 2-(hydroxymethyl) tetrahydrofuranyl residue, was synthesized in order to act as a model for damaged nucleic acid probes. Prepared oligodeoxyribonucleotides containing one, two or three abasic sites were hybridized to complementary sequences immobilized on a gold surface using the neutravidin-biotin interaction for study by thickness shear mode acoustic wave detector. Measurement of the complex electrical impedance of an AT-cut quartz device with immobilized biotinylated nucleotide allowed the detection of changes of series resonance frequency, Deltafs, and motional resistance, Rm, associated with duplex formation. The changes as detected by the acoustic wave method correlated well with the thermostability of DNA duplexes in solution. With respect to the latter, UV-monitored melting curves indicate that both the number of sites and their localization in the double-stranded structure influence the amount by which a 19 b.p. duplex is destabilized. The presence of 3 abasic sites completely destabilized the DNA duplex.

Molecular level damages of low power pulsed laser radiation in a marine bacterium Pseudoalteromonas carrageenovora

AIM

To study the molecular level damages in a marine bacterium, Pseudoalteromonas carrageenovora, exposed to low power pulsed laser radiation from an Nd:YAG laser.

METHODS AND RESULTS

The laser damages in bacterial DNA were monitored by studying the formation of apurinic/apyrimidinic (AP) sites. Molecular probe kits were used for this purpose. Occurrence of lesions in the cell walls was monitored under a transmission electron microscope (TEM). The results showed that laser radiation significantly increased the number of AP sites in the bacterial DNA. This increase corresponded to the laser fluence (J cm(-2)) and to the duration of laser irradiation. TEM observation showed the occurrence of lesions in bacterial cell walls upon laser irradiation.

CONCLUSIONS

It is concluded that bacteria exposed to laser irradiation suffers DNA damages and resulted in broken cell walls. These events led to bacterial mortality. These are in addition to the mechanisms reported earlier such as the photochemical reactions occurring inside the cells upon exposure to low power laser.

SIGNIFICANCE AND IMPACT OF THE STUDY

These results help us to understand the mechanisms of bacterial mortality on exposure to low power pulsed laser irradiation and are useful in formulating a laser treatment strategy to kill bacteria.

Determination of apurinic/apyrimidinic lesions in DNA with high-performance liquid chromatography and tandem mass spectrometry

A new method has been developed to accurately measure apurinic and apyrimidinic (AP) DNA damage sites, which are lesions in DNA formed by loss of a nucleobase from oxidative stress or carcinogen adducts. If AP sites are left unrepaired (or if improperly repaired), these sites can lead to DNA mutations that may ultimately result in the formation of cancer. Hence, detection of AP sites may provide a useful indicator of exposure and susceptibility to chemical carcinogens and oxidative stress. AP detection is currently accomplished by immunodetection methods using an aldehyde reactive probe [Nakamura, J., Walker, V. E., Upton, P. B., Chiang, S.-Y., Kow, Y. W., and Swenberg, J. A. (1998) Cancer Res. 58, 222-225; Atamna, H., Cheung, I., and Ames, B. N. (2000) Proc. Natl. Acad. Sci. U.S.A. 97, 686-691]; however, these approaches lack the specificity required for unequivocal identification of the AP site. Therefore, we have developed an accurate method based on mass spectrometry detection of AP sites from AP DNA that have been prelabeled with O-4-nitrobenzylhydroxylamine (NBHA). Once labeled and once the excess labeling agent has been removed, enzymatic digestion of DNA to monomeric subunits can be accomplished, followed by isolation and detection with high-performance liquid chromatography coupled to electrospray ionization tandem mass spectrometry (HPLC-ESI-MS/MS). Optimization and validation of the experimental procedures and detection limits have been established using a model DNA oligomer (11-mer) containing uracil. Enzymatic removal of uracil with uracil glycosylase generates well-defined AP sites in both single- and double-stranded DNA. The addition of NBHA labels the AP site in the oligomer, creating a labeled 11-mer. HPLC-ESI-MS/MS in the negative ionization mode was used to monitor and confirm binding of NBHA to the AP oligomer. The NBHA-tagged oligomer underwent endo- and exonuclease digestion to the 5'-deoxyribose monophosphate (5'-dRp) level, thereby releasing free 5'-dRp-NBHA. The 5'-dRp-NBHA product was partially purified by solid phase extraction and quantified by LC-MS/MS using several transitions of the deprotonated molecule ([M - H]- at m/z 363) and isotopically labeled 5'-dRp-NBHA as an internal standard. Further experiments with 5',3'-bisphosphate-deoxyribose and heat/acid-treated calf thymus DNA showed similar labeling, digestion, and detection results. Initial results show a quantification limit with 100 mug of DNA to be 100 fmol (three abasic sites per 10(7) bases).

Strong and selective binding of amiloride to thymine base opposite AP sites in DNA duplexes: simultaneous binding to DNA phosphate backbone

Amiloride (N-amidino-3,5-diamino-6-chloro-pyrazinecarboxamide hydrochloride) has two sets of hydrogen-bond forming sites suitable for target nucleotides and the phosphodiester DNA backbone by which a thymine base opposite an abasic site in DNA duplexes can be recognized with high selectivity and affinity, and it is applicable to the fluorescence detection of thymidine-related SNPs (single-nucleotide polymorphisms) of PCR amplification products.

α- and β-Stilbenosides as base-pair surrogates in DNA hairpins

The synthesis, structure, and optical spectroscopy of hairpin oligonucleotide conjugates possessing synthetic stilbene C-nucleosides (stilbenosides) are reported. Synthetic methods for selective preparation of both the alpha- and beta-stilbenosides have been developed. Both anomers are effective in stabilizing hairpin structures when used as capping groups at the open end of the hairpin base-pair domain. However, only the beta-anomer effectively stabilizes the hairpin structure when located in the interior of the base-pair domain opposite an abasic site. Similar results are obtained for hairpins possessing two stilbenosides, either adjacent to each other or with one intervening base-pair. Molecular dynamics simulations are employed to obtain averaged structures for these conjugates. The calculated structures for the capped hairpins formed with either anomer show effective pi-stacking with the adjacent base-pair. The calculated structures for the internal stilbenosides show that the alpha- and beta-anomers form extrahelical and intrahelical structures, respectively. The relative orientations of the two stilbenes in the bis-stilbenosides have been studied using a combination of exciton-coupled circular dichroism spectroscopy and molecular modeling.

Characterization of the aldehyde reactive probe reaction with AP-sites in DNA: influence of AP-lyase on adduct stability

Alkoxyamines react with the open-chain aldehyde form of AP-sites in DNA to produce open-chain aldehyde oximes. Here we characterize the effect of AP-site cleavage by yeast AP-endonuclease 1 (APN1) or T4 pyrimidine dimer DNA glycosylase/AP-lyase (T4 Pdg) on the efficiency and stability of the alkoxyamine aldehyde reactive probe (ARP) condensation reaction with AP-sites. The results indicate that (1) reaction of ARP with the open-chain aldehyde equilibrium form of the AP-site was less efficient than with the 3'-alpha,beta-unsaturated aldehyde produced by T4 Pdg; (2) the dRP moiety was least reactive with ARP; (3) both the AP-site and 3'-alpha,beta-unsaturated aldehyde were stable with regard to reaction with ARP over a 30-min incubation period at 37 degrees C; and (4) ARP adducted to the open-chain aldehyde form of the AP-site could be replaced by methoxyamine, but the 3'-alpha,beta-unsaturated aldehyde ARP oxime was stable against methoxyamine attack.

Impact of the C1' configuration of abasic sites on DNA duplex structure

Naturally occurring abasic sites in DNA exist as an equilibrium mixture of the aldehyde, the hydrated aldehyde, and the hemiacetal forms (dominant). The influence of the configuration of the C1' hydroxyl group of the hemiacetal form on duplex structure and abasic site repair has been examined using novel carbocyclic analogues. Both the alpha- and beta-forms of this novel abasic site were introduced into oligomeric DNA using the standard DMT-phosphoramidite approach in an automated solid-phase synthesizer. Solution structures of the d(CGTACXCATGC).d(GCATGAGTACG) duplex (where X is the alpha- or beta-anomer of the carbocyclic abasic site analogue) were determined by NMR spectroscopy and restrained molecular dynamics simulations. The structures were only minimally perturbed by the presence of either anomer of the abasic site. All residues adopted an anti conformation, and Watson-Crick alignments were observed on all base pairs of the duplexes. At the lesion site, the abasic residues and their partner adenines showed increased dynamic behavior but adopted intrahelical positions in the final refined structures. Incision of duplexes having the alpha- or beta-anomer of the carbocyclic abasic site by human AP endonuclease showed that the enzyme recognizes both configurations of the lesion and nicks the DNA backbone with similar efficiency. Our results challenge the suggestion that Ape1 is stereoselective and imply a plasticity at the active site of the enzyme for accommodating either anomer of the lesion.

Solution structure of a DNA duplex containing an alpha-anomeric adenosine: insights into substrate recognition by endonuclease IV

The cytotoxic alpha anomer of adenosine, generated in situ by radicals, must be recognized and repaired to maintain genomic stability. Endonuclease IV (Endo IV), a member of the base excision repair (BER) enzyme family, in addition to acting on abasic sites, has the auxiliary function of removing this mutagenic nucleotide in Escherichia coli. We have employed enzymatic, thermodynamic, and structural studies on DNA duplexes containing a central alpha-anomeric adenosine residue to characterize the role of DNA structure on recognition and catalysis by Endo IV. The enzyme recognizes and cleaves our alphaA-containing DNA duplexes at the site of the modification. The NMR solution structure of the DNA decamer duplex establishes that the single alpha-anomeric adenosine residue is intrahelical and stacks in a reverse Watson-Crick fashion consistent with the slight decrease in thermostability. However, the presence of this lesion confers significant changes to the global duplex conformation, resulting from a kink of the helical axis into the major groove and an opening of the minor groove emanating from the alpha-anomeric site. Interestingly, the conformation of the flanking base-paired segments is not greatly altered from a B-type conformation. The global structural changes caused by this lesion place the DNA along the conformational path leading to the DNA structure observed in the complex. Thus, it appears that the alpha-anomeric lesion facilitates recognition by Endo IV.

Near-field optical imaging of abasic sites on a single DNA molecule

Scanning near-field optical microscopy (SNOM) imaging was performed to allow for the direct visualization of damaged sites on individual DNA molecules to a scale of a few tens of nanometers. Fluorescence in situ hybridization on extended DNA molecules was modified to detect a single abasic site. Abasic sites were specifically labelled with a biotinlylated aldehyde-reactive probe and fluorochrome-conjugated streptavidin. By optimizing the performance of the SNOM technique, we could obtain high contrast near-field optical images that enabled high-resolution near-field fluorescence imaging using optical fiber probes with small aperture sizes. High-resolution near-field fluorescence imaging demonstrated that two abasic sites within a distance of 120 nm are clearly obtainable, something which is not possible using conventional fluorescence in situ hybridization combined with far-field fluorescence microscopy.

Structure and dynamics of thioguanine-modified duplex DNA

Mercaptopurine and thioguanine, two of the most widely used antileukemic agents, exert their cytotoxic, therapeutic effects by being incorporated into DNA as deoxy-6-thioguanosine. However, the molecular mechanism(s) by which incorporation of these thiopurines into DNA translates into cytotoxicity is unknown. The solution structure of thioguanine-modified duplex DNA presented here shows that the effects of the modification on DNA structure were subtle and localized to the modified base pair. Specifically, thioguanine existed in the keto form, formed weakened Watson-Crick hydrogen bonds with cytosine and caused a modest approximately 10 degrees opening of the modified base pair toward the major groove. In contrast, thioguanine significantly altered base pair dynamics, causing an approximately 80-fold decrease in the base pair lifetime with cytosine compared with normal guanine. This perturbation was consistent with the approximately 6 degrees C decrease in DNA melting temperature of the modified oligonucleotide, the 1.13 ppm upfield shift of the thioguanine imino proton resonance, and the large increase in the exchange rate of the thioguanine imino proton with water. Our studies provide new mechanistic insight into the effects of thioguanine incorporation into DNA at the level of DNA structure and dynamics, provide explanations for the effects of thioguanine incorporation on the activity of DNA-processing enzymes, and provide a molecular basis for the specific recognition of thioguanine-substituted sites by proteins. These combined effects likely cooperate to produce the cellular responses that underlie the therapeutic effects of thiopurines.

Combining NMR spectral and structural data to form models of polychlorinated dibenzodioxins, dibenzofurans, and biphenyls binding to the AhR

A three-dimensional quantitative spectrometric data-activity relationship (3D-QSDAR) modeling technique which uses NMR spectral and structural information that is combined in a 3D-connectivity matrix has been developed. A 3D-connectivity matrix was built by displaying all possible assigned carbon NMR chemical shifts, carbon-to-carbon connections, and distances between the carbons. Two-dimensional 13C-13C COSY and 2D slices from the distance dimension of the 3D-connectivity matrix were used to produce a relationship among the 2D spectral patterns for polychlorinated dibenzofurans, dibenzodioxins, and biphenyls (PCDFs, PCDDs, and PCBs respectively) binding to the aryl hydrocarbon receptor (AhR). We refer to this technique as comparative structural connectivity spectral analysis (CoSCoSA) modeling. All CoSCoSA models were developed using forward multiple linear regression analysis of the predicted 13C NMR structure-connectivity spectral bins. A CoSCoSA model for 26 PCDFs had an explained variance (r2) of 0.93 and an average leave-four-out cross-validated variance (q(2)4) of 0.89. A CoSCoSA model for 14 PCDDs produced an r2 of 0.90 and an average leave-two-out cross-validated variance (q(2)2) of 0.79. One CoSCoSA model for 12 PCBs gave an r2 of 0.91 and an average q(2)2 of 0.80. Another CoSCoSA model for all 52 compounds had an r2 of 0.85 and an average q(2)2 of 0.52. Major benefits of CoSCoSA modeling include ease of development since the technique does not use molecular docking routines.

Evidence for multiple imino intermediates and identification of reactive nucleophiles in peptide-catalyzed beta-elimination at abasic sites

Prior investigations have demonstrated that peptides containing a single aromatic residue flanked by basic ones, such as Lys-Trp-Lys, can incise the phosphodiester backbone of duplex DNA at an AP site via beta-elimination. An amine serves as the reactive nucleophile to attack C1' on the ring-open deoxyribose sugar to form a transient peptide-DNA imino (Schiff base) intermediate, which may be isolated as a stable covalent species under reducing conditions. In the current study, we use this methodology to demonstrate that peptide-catalyzed beta-elimination proceeds via the formation of two Schiff base intermediates, one of which was covalently trapped prior to strand incision and the other following strand incision. N-Terminal acetylation of reactive peptides significantly inhibited formation of a trapped Schiff base complex; thus, we demonstrate for the first time that the preferred reactive nucleophile for peptides catalyzing strand incision is the N-terminal alpha-amino group, not an epsilon-amino group located on a lysine residue as previously postulated. Trapping reactions in which the central tryptophan residue was changed to alanine did not have a significant impact on the efficiency of Schiff base formation, indicating that the presence of an aromatic residue is dispensable for the step prior to peptide-catalyzed beta-elimination. Interestingly, the methodology presented here affords a convenient means for covalently attaching an array of peptides onto AP site-containing DNA in a site-specific fashion. We suggest that the generation of such DNA-peptide cross-links may provide utility in studying the repair of biologically significant DNA-protein cross-link damage as DNA-peptide complexes may mimic intermediate structures along a repair pathway for DNA-protein cross-links.

Structural study of DNA duplexes containing the (6-4) photoproduct by fluorescence resonance energy transfer

Fluorescence resonance energy transfer (FRET) experiments have been performed to elucidate the structural features of oligonucleotide duplexes containing the pyrimidine(6-4)pyrimidone photoproduct, which is one of the major DNA lesions formed at dipyrimidine sites by UV light. Synthetic 32mer duplexes with and without the (6-4) photoproduct were prepared and fluorescein and tetramethylrhodamine were attached, as a donor and an acceptor, respectively, to the aminohexyl linker at the C5 position of thymine in each strand. Steady-state and time-resolved analyses revealed that both the FRET efficiency and the fluorescence lifetime of the duplex containing the (6-4) photoproduct were almost identical to those of the undamaged duplex, while marked differences were observed for a cisplatin-modified duplex, as a model of kinked DNA. Lifetime measurements of a series of duplexes containing the (6-4) photoproduct, in which the fluorescein position was changed systematically, revealed a small unwinding at the damage site, but did not suggest a kinked structure. These results indicate that formation of the (6-4) photoproduct induces only a small change in the DNA structure, in contrast to the large kink at the (6-4) photoproduct site reported in an NMR study.

Oligonucleotides with bistranded abasic sites interfere with substrate binding and catalysis by human apurinic/apyrimidinic endonuclease

Apurinic/apyrimidinic endonuclease (AP endo) is a key enzyme in oxidative damage DNA repair. The enzyme, which repairs abasic sites, makes a single nick 5' to the phosphodeoxyribose, leaving a free 3'-hydroxyl. We recently described single turnover kinetics for human recombinant AP endo acting on an oligonucleotide with a single abasic site. We hypothesized that the structural changes induced by the presence of a second abasic site might provide insight into how AP endo recognizes the first abasic site. Here we performed steady state and single turnover experiments using bistranded abasic site substrates, with the second site located on the complementary strand to the one being followed and either opposite to the first or displaced in the 5' direction. All sites on the complementary strand were within half a helical turn of the first. The catalytic efficiency was reduced 80 to 96% and the Kd for substrate binding and dissociation was elevated 40- to 125-fold. The smaller changes occurred when the second site was opposite the first site or displaced by four nucleotides. In addition, if the second abasic site was directly across the helix or displaced by 1 or 3 nucleotides from the first abasic site, cleavage of the first abasic site was subject to apparent substrate inhibition, which did not occur if the second abasic site was displaced by four nucleotides from the first. While a substrate containing a nick without a phosphodeoxyribose on the contralateral strand abasic site did not inhibit nicking of the first strand, a substrate with a nicked abasic site on the contralateral strand was an even stronger inhibitor of enzyme action than an oligonucleotide containing the corresponding abasic site on each strand. Consequently, the inhibitory effect of the second abasic site is probably the result of prior cleavage of the abasic site on the contralateral strand with resulting distortions to the DNA helix that interfere with enzyme binding and/or cleavage.

RNA-DNA hybrids containing damaged DNA are substrates for RNase H

During the replication of the lagging strand, RNA-DNA hybrids are formed and the RNA is subsequently degraded by the action of RNase H. Little is known about the effects of damaged DNA on lagging strand replication and subsequent RNA removal. The rates and sites of digestion by E. coli RNase H of RNA-DNA hybrids containing either a thymine glycol or urea site in the DNA strand have been examined. The cleavage patterns for duplexes containing thymine glycol or urea differ from that of a fully complementary duplex. There is one major product of the digestion of the fully complementary hybrid, but three products are formed in the reactions with the hybrids containing damaged DNAs. Cleavage is partially redirected to the position adjacent to the damaged sites. The overall rate of cleavage of these hybrids containing damaged DNA is comparable to that of the fully complementary duplex. These results indicate that the cleavage of RNA-DNA hybrids by RNase H is less selective when a damaged site is present in the DNA strand.

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.

Multiple cleavage activities of endonuclease V from Thermotoga maritima: recognition and strand nicking mechanism

Endonuclease V is a deoxyinosine 3'-endonuclease which initiates removal of inosine from damaged DNA. A thermostable endonuclease V from the hyperthermophilic bacterium Thermotoga maritima has been cloned and expressed in Escherichia coli. The DNA recognition and reaction mechanisms were probed with both double-stranded and single-stranded oligonucleotide substrates which contained inosine, abasic site (AP site), uracil, or mismatches. Gel mobility shift and kinetic analyses indicate that the enzyme remains bound to the cleaved inosine product. This slow product release may be required in vivo to ensure an orderly process of repairing deaminated DNA. When the enzyme is in excess, the primary nicked products experience a second nicking event on the complementary strand, leading to a double-stranded break. Cleavage at AP sites suggests that the enzyme may use a combination of base contacts and local distortion for recognition. The weak binding to uracil sites may preclude the enzyme from playing a significant role in repair of such sites, which may be occupied by uracil-specific DNA glycosylases. Analysis of cleavage patterns of all 12 natural mismatched base pairs suggests that purine bases are preferrentially cleaved, showing a general hierarchy of A = G > T > C. A model accounting for the recognition and strand nicking mechanism of endonuclease V is presented.

Detection of abasic sites on individual DNA molecules using atomic force microscopy

We have developed an atomic force microscopy-based method for detecting abasic sites (AP sites) on individual DNA molecules. By using uracil and uracil DNA glycosylase, we first prepared a 250-bp DNA template consisting of two AP sites at specific locations. We then detected the AP sites by marking them with biotinylated aldehyde-reactive probes and monomeric avidin. We demonstrate here that (i) the location of monomeric avidin bound on a single DNA molecule was detectable by atomic force microscopy; (ii) the observed location of avidin was in good agreement to the predicted AP sites at a few nanometer resolution; and (iii) by end-labeling the 5'-terminus of one DNA strand, the AP sites were determined without directional ambiguity. The technique described here will provide a sensitive way of locating AP sites and contribute to screen DNA damages from individual molecules.

15-mer DNA duplexes containing an abasic site are thermodynamically more stable with adjacent purines than with pyrimidines

Abasic site (AP)-containing duplexes, with flanking adenine (A) or cytosine (C) bases, were shown to be more stable with flanking A than with C bases [Sági, J., Hang, B., and Singer, B. (1999) Chem. Res. Toxicol. 12, 917-923]. We investigated whether the lower-magnitude destabilization by an AP site, with A neighbors, is a general effect of the purine versus the pyrimidine neighbors. Duplex stability, as compared to that of the corresponding control duplexes, was markedly decreased by the incorporation of the AP site (x) opposite any of the four bases. However, for the duplexes containing T, A, or C opposite the AP site, replacement of the symmetric doublet flanking pyrimidine bases with purines resulted in a smaller destabilization effect. The average stabilizing effect of the symmetric doublet purine neighbors of an AP site opposite T, A, or C bases was 3.2 degrees C (DeltaT(m)) and 1.3 kcal/mol (DeltaDeltaG degrees (37)) compared to those of pyrimidine neighbors. In contrast, a G.AP pair reduced or eliminated the differential effect of the neighbors. Using unrestrained molecular dynamics, it was shown that for the duplexes containing T opposite the AP site, with doublet pyrimidine neighbors, there was a larger magnitude of curvature around the lesion site than for the duplexes with the purines flanking the AP site. Purines flanking the AP site tend to shift toward each other, creating overlap, in contrast to the flanking pyrimidines. This indicates the possibility of stacking between purine bases at the AP site and can be the reason for the observed smaller thermodynamic destabilization of the duplexes with the AAxAA and GGxGG central sequences, as compared to those with TTxTT and CCxCC sequences. This work showed that for an AP site the GC content is not the only determinant of duplex stability, but rather is influenced more by whether purines or pyrimidines flank the AP site.

Conformation and dynamics of abasic sites in DNA investigated by time-resolved fluorescence of 2-aminopurine

Abasic sites are highly mutagenic lesions in DNA that arise as intermediates in the excision repair of modified bases. These sites are generated by the action of damage-specific DNA glycosylases and are converted into downstream intermediates by the specific activity of apurinic/apyrimidinic endonucleases. Enzymes in both families have been observed in crystal structures to impose deformations on the abasic-site DNA, including DNA kinking and base flipping. On the basis of these apparent protein-induced deformations, we propose that altered conformation and dynamics of abasic sites may contribute to the specificity of these repair enzymes. Previously, measurements of the steady-state fluorescence of the adenine analogue 2-aminopurine (2AP) opposite an abasic site demonstrated that binding of divalent cations could induce a conformational change that increased the accessibility of 2AP to solute quenching [Stivers, J. T. (1998) Nucleic Acids Res. 26, 3837-44]. We have performed time-resolved fluorescence experiments to characterize the states involved in this conformational change. Interpretation of these studies is based on a recently developed model attributing the static and dynamic fluorescence quenching of 2AP in DNA to aromatic stacking and collisional interactions with neighboring bases, respectively (see the preceding paper in this issue). The time-resolved fluorescence results indicate that divalent cation binding shifts the equilibrium of the abasic site between two conformations: a "closed" state, characterized by short average fluorescence lifetime and complex decay kinetics, and an "open" state, characterized by monoexponential decay with lifetime approximately that of the free nucleoside. Because the lifetime and intensity decay kinetics of 2AP incorporated into DNA are sensitive primarily to collisional interactions with the neighboring bases, the absence of dynamic quenching in the open state strongly suggests that the fluorescent base is extrahelical in this conformation. Consistent with this interpretation, time-resolved quenching studies reveal that the open state is accessible to solute quenching by potassium iodide, but the closed state is not. Greater static quenching is observed in the abasic site when the fluorescent base is flanked by 5'- and 3'-thymines than in the context of 5'- and 3'-adenines, indicating that 2AP is more stacked with the neighboring bases in the former sequence. These results imply that the conformation of the abasic site varies in a sequence-dependent manner. Undamaged sequences in which the abasic site is replaced by thymine do not exhibit an open state and have different levels of both static and dynamic quenching than their damaged homologues. These differences in structure and dynamics may be significant determinants of the high specific affinity of repair enzymes for the abasic site.

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.

Structures of the potassium-saturated, 2:1, and intermediate, 1:1, forms of a quadruplex DNA

Potassium can stabilize the formation of chair- or edge-type quadruplex DNA structures and appears to be the only naturally occurring cation that can do so. As quadruplex DNAs may be important in the structure of telomere, centromere, triplet repeat and other DNAs, information about the details of the potassium-quadruplex DNA interactions are of interest. The structures of the 1:1 and the fully saturated, 2:1, potassium-DNA complexes of d(GGTTGGTGTGGTTGG) have been determined using the combination of experimental NMR results and restrained molecular dynamics simulations. The refined structures have been used to model the interactions at the potassium binding sites. Comparison of the 1:1 and 2:1 potassium:DNA structures indicates how potassium binding can determine the folding pattern of the DNA. In each binding site potassium interacts with the carbonyl oxygens of both the loop thymine residues and the guanine residues of the adjacent quartet.

Human apurinic/apyrimidinic endonuclease is processive

Apurinic/apyrimidinic endonuclease (AP endo) is believed to play a critical role in repair of oxidative damage of DNA and is proposed to initiate repair of most abasic sites in the base excision repair pathway. AP endo makes a single nick 5' to an abasic site in double-stranded DNA. In this study, we investigated whether AP endo locates an abasic site through a processive or a distributive mechanism. We used a linear multi-abasic site substrate (concatemer), synthesized by ligating together identical 25-nucleotide monomeric units (25-mers). We first determined that the 25-mer monomer from which the concatemers were prepared was nicked by AP endo in a fashion similar to that of the previously published 49-mer substrate with a different sequence. Steady state parameters K(m) and k(cat) and single-turnover parameters for substrate binding were comparable to previously published values. Using the multi-abasic site concatemer, we demonstrated that AP endo was capable of cleaving approximately seven to eight abasic sites, traveling at least 200 nucleotides, before dissociating from its substrate. Thus, AP endo, like uracil DNA glycosylase, behaves in a quasi processive fashion. Processivity could be separated from catalysis, since processivity was maximal at 25 mM NaCl, while the rate of cleavage was maximal at 125 mM salt. In short, nicking activity was maximized close to physiological salt molarities while processivity was midrange at physiological salt concentrations. The latter is likely to be subject to tight regulation by small changes in ionic strength.