Flexibility and curvature of duplex DNA containing mismatched sites as a function of temperature

The flexibility and curvature of duplex DNAs containing mismatched sites have been monitored as a function of temperature. The diffusion coefficients are dependent on the flexibility and the curvature of the DNA, and these have been determined by NMR-based methods. The diffusion coefficients, D, depend on a Boltzmann term and the viscosity of the solvent, eta, which is also temperature dependent. To analyze the temperature dependence of the diffusion results, the shape function, S(f) = etaD/T, is used. The shape functions do not have the viscosity and temperature dependence of the diffusion coefficients. The presence of mismatched sites significantly enhances the shape function of duplex DNA at all temperatures examined. The observed increases in the shape functions are attributed to the mismatched sites acting as localized flexible joints. The results on the temperature dependence of the shape functions, the optical absorbance, and the proton chemical shifts indicate that local melting at, and adjacent to, mismatched site occurs at a lower temperature than the overall melting of the duplexes. The localized melting gives rise to a considerable increase in the shape function. The contribution of the curvature of the mismatched sites to the enhanced diffusion has been examined. A DNA with mismatches that are in phase with respect to the helical repeat and a DNA which has the mismatches out of phase with respect to the helical repeat have been examined. The results indicate that mismatched sites have modest curvature.     

Binding of specific DNA base-pair mismatches by N-methylpurine-DNA glycosylase and its implication in initial damage recognition

Most DNA glycosylases including N-methylpurine-DNA glycosylase (MPG), which initiate DNA base excision repair, have a wide substrate range of damaged or altered bases in duplex DNA. In contrast, uracil-DNA glycosylase (UDG) is specific for uracil and excises it from both single-stranded and duplex DNAs. Here we show by DNA footprinting analysis that MPG, but not UDG, bound to base-pair mismatches especially to less stable pyrimidine-pyrimidine pairs, without catalyzing detectable base cleavage. Thermal denaturation studies of these normal and damaged (e.g. 1,N(6)-ethenoadenine, varepsilonA) base mispairs indicate that duplex instability rather than exact fit of the flipped out damaged base in the catalytic pocket is a major determinant in the initial recognition of damage by MPG. Finally, based on our determination of binding affinity and catalytic efficiency we conclude that the initial recognition of substrate base lesions by MPG is dependent on the ease of flipping of the base from unstable pairs to a flexible catalytic pocket.     

Flexibility of duplex DNA on the submicrosecond timescale

Using a site-specific, Electron Paramagnetic Resonance (EPR)-active spin probe that is more rigidly locked to the DNA than any previously reported, the internal dynamics of duplex DNAs in solution were studied. EPR spectra of linear duplex DNAs containing 14-100 base pairs were acquired and simulated by the stochastic Liouville equation for anisotropic rotational diffusion using the diffusion tensor for a right circular cylinder. Internal motions have previously been assumed to be on a rapid enough time scale that they caused an averaging of the spin interactions. This assumption, however, was found to be inconsistent with the experimental data. The weakly bending rod model is modified to take into account the finite relaxation times of the internal modes and applied to analyze the EPR spectra. With this modification, the dependence of the oscillation amplitude of the probe on position along the DNA was in good agreement with the predictions of the weakly bending rod theory. From the length and position dependence of the internal flexibility of the DNA, a submicrosecond dynamic bending persistence length of around 1500 to 1700 A was found. Schellman and Harvey (Biophys. Chem. 55:95-114, 1995) have estimated that, out of the total persistence length of duplex DNA, believed to be about 500 A, approximately 1500 A is accounted for by static bends and 750 A by fluctuating bends. A measured dynamic persistence length of around 1500 A leads to the suggestion that there are additional conformations of the DNA that relax on a longer time scale than that accessible by linear CW-EPR. These measurements are the first direct determination of the dynamic flexibility of duplex DNA in 0.1 M salt.     

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.     

PELDOR analysis of enzyme-induced structural changes in damaged DNA duplexes

PELDOR (pulsed electron-electron double resonance) spectroscopy was applied to determine spin-spin distances in spin-labeled DNA duplexes (13-mer and 17-mer) containing the damaged sites 8-oxoguanine or uncleavable abasic site analogue tetrahydrofuran. The lesions were located in one strand of the DNA, and two nitroxyl spin labels were attached at the 5'- and 3'-ends of the complementary strand. PELDOR data allow us to obtain distances between the two spin labels in DNAs, which turned out to be around 5 nm for the 13-mer DNA and around 6 nm for 17-mer DNA. Results of PELDOR measurements were supported by molecular dynamics calculations. Study of the interaction of DNA fragments with DNA repair enzyme 8-oxoguanine-DNA glycosylase from E. coli (Fpg protein) showed that this interaction leads to a noticeable decrease of the distance between spin labels, which indicates the enzyme-induced bending of the DNA duplex. This bending may be important for the mechanisms of recognition of damaged sites by DNA repair enzymes.     

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.     

Effects of the presence of an aldehydic abasic site on the thermal stability and rates of helix opening and closing of duplex DNA.

The presence of an abasic site in duplex DNA lowers the thermodynamic stability, as monitored by the optical melting temperature, and decreases the rate of imino proton exchange with water, by about an order of magnitude, as monitored by direct measurement of both the exchange lifetimes and the imino proton T1S. The exchange lifetimes of the imino protons with water as a function of base catalyst concentration were analyzed to determine the origin of the effect of the abasic site on imino exchange lifetimes. Analysis of the results showed that the helix opening rate is not significantly changed by the presence of an abasic site. The differences in exchange lifetimes are attributed to a faster helix closing rate in the presence of an abasic site. The faster rate of helix closing may be an important contribution to the stability of abasic sites in duplex DNA to base-catalyzed elimination reaction. It is noted that duplex DNAs containing analogues of the aldehydic abasic site apparently do not exhibit these exchange lifetime effects.     

Linear free energy correlations for enzymatic base flipping: how do damaged base pairs facilitate specific recognition?

To efficiently maintain their genomic integrity, DNA repair glycosylases must exhibit high catalytic specificity for their cognate damaged bases using an extrahelical recognition mechanism. One possible contribution to specificity is the weak base pairing and inherent instability of damaged sites which may lead to increased extrahelicity of the damaged base and enhanced recognition of these sites. This model predicts that the binding affinity of the enzyme should increase as the thermodynamic stability of the lesion base pair decreases, because less work is required to extrude the base into its active site. We have tested this hypothesis with uracil DNA glycosylase (UDG) by constructing a series of DNA duplexes containing a single uracil (U) opposite a variety of bases (X) that formed from zero to three hydrogen bonds with U. Linear free energy (LFE) relationships were observed that correlated UDG binding affinity with the entropy and enthalpy of duplex melting, and the dynamic accessibility of the damaged site to chemical oxidation. These LFEs indicate that the increased conformational freedom of the damaged site brought about by enthalpic destabilization of the base pair promotes the formation of extrahelical states that enhance specific recognition by as much as 3000-fold. However, given the small stability differences between normal base pairs and U.A or U.G base pairs, relative base pair stability contributes little to the >10(6)-fold discrimination of UDG for uracil sites in cellular DNA. In contrast, the intrinsic instability of other more egregious DNA lesions may contribute significantly to the specificity of other DNA repair enzymes that bind to extrahelical bases.     

Complexity in the binding of minor groove agents: netropsin has two thermodynamically different DNA binding modes at a single site

Structural results with minor groove binding agents, such as netropsin, have provided detailed, atomic level views of DNA molecular recognition. Solution studies, however, indicate that there is complexity in the binding of minor groove agents to a single site. Netropsin, for example, has two DNA binding enthalpies in isothermal titration calorimetry (ITC) experiments that indicate the compound simultaneously forms two thermodynamically different complexes at a single AATT site. Two proposals for the origin of this unusual observation have been developed: (i) two different bound species of netropsin at single binding sites and (ii) a netropsin induced DNA hairpin to duplex transition. To develop a better understanding of DNA recognition complexity, the two proposals have been tested with several DNAs and the methods of mass spectrometry (MS), polyacrylamide gel electrophoresis (PAGE) and nuclear magnetic resonance spectroscopy in addition to ITC. All of the methods with all of the DNAs investigated clearly shows that netropsin forms two different complexes at AATT sites, and that the proposal for an induced hairpin to duplex transition in this system is incorrect.     

Restriction endonucleases HindII and TaqI cleave DNA with mismatched nucleotides within their recognition sequences.

Restriction endonucleases HindII and TaqI, but not SalI, were found to efficiently cleave synthetic hexadecanucleotide duplexes which contained either an A/C or a G/T mismatch within their respective restriction sites. Double-stranded M13 DNAs with identical mismatches were also cleaved under the assay conditions. These results suggest that the distortion of the DNA duplex, caused by these purine/pyrimidine mismatches is not sufficiently large so as to interfere with the recognition and the subsequent cleavage of the DNA by these two enzymes. HindII and SalI, but not TaqI, were furthermore shown to hydrolyze the two strands of the duplex with different rates. The differences between the mode of recognition of their respective restriction sites by these three enzymes are discussed.     

Sensing DNA damage by PARP-like fingers

PARP-like zinc fingers are protein modules, initially described as nick-sensors of poly(ADP-ribosyl)-polymerases (PARPs), which are found at the N-terminus of different DNA repair enzymes. I chose to study the role of PARP-like fingers in AtZDP, a 3′ DNA phosphoesterase, which is the only known enzyme provided with three such finger domains. Here I show that PARP-like fingers can maintain AtZDP onto damaged DNA sites without interfering with its DNA end repair functions. Damage recognition by AtZDP fingers, in fact, relies on the presence of flexible joints within double-strand DNA and does not entail DNA ends. A single AtZDP finger is already capable of specific recognition. Two fingers strengthen the binding and extend the contacts on the bound DNA. A third finger further enhances the specific binding to damaged DNA sites. Unexpectedly, gaps but not nicks are bound by AtZDP fingers, suggesting that nicks on a naked DNA template do not provide enough flexibility for the recognition. Altogether these results indicate that AtZDP PARP-like fingers, might have a role in positioning the enzyme at sites of enhanced helical flexibility, where single-strand DNA breaks are present or are prone to occur.     

Synthesis and binding properties of new selective ligands for the nucleobase opposite the AP site

DNA is continuously damaged by endogenous and exogenous factors such as oxidative stress or DNA alkylating agents. These damaged nucleobases are removed by DNA N-glycosylase and form apurinic/apyrimidinic sites (AP sites) as intermediates in the base excision repair (BER) pathway. AP sites are also representative DNA damages formed by spontaneous hydrolysis. The AP sites block DNA polymerase and a mismatch nucleobase is inserted opposite the AP sites by polymerization to cause acute toxicities and mutations. Thus, AP site specific compounds have attracted much attention for therapeutic and diagnostic purposes. In this study, we have developed nucleobase-polyamine conjugates as the AP site binding ligand by expecting that the nucleobase part would play a role in the specific recognition of the nucleobase opposite the AP site by the Watson-Crick base pair formation and that the polyamine part should contribute to the access of the ligand to the AP site by a non-specific interaction to the DNA phosphate backbone. The nucleobase conjugated with 3,3'-diaminodipropylamine (A-ligand, G-ligand, C-ligand, T-ligand and U-ligand) showed a specific stabilization of the duplex containing the AP site depending on the complementary combination with the nucleobase opposite the AP site; that is A-ligand to T, G-ligand to C, C-ligand to G, T- and U-ligand to A. The thermodynamic binding parameters clearly indicated that the specific stabilization is due to specific binding of the ligands to the complementary AP site. These results have suggested that the complementary base pairs of the Watson-Crick type are formed at the AP site.     

Interaction of nucleotide excision repair factors RPA and XPA with DNA containing bulky photoreactive groups imitating damages

Interaction of nucleotide excision repair factors--replication protein A (RPA) and Xeroderma pigmentosum complementing group A protein (XPA)--with DNA structures containing nucleotides with bulky photoreactive groups imitating damaged nucleotides was investigated. Efficiency of photoaffinity modification of two proteins by photoreactive DNAs varied depending on DNA structure and type of photoreactive group. The secondary structure of DNA and, first of all, the presence of extended single-stranded parts plays a key role in recognition by RPA. However, it was shown that RPA efficiently interacts with DNA duplex containing a bulky substituent at the 5 -end of a nick. XPA was shown to prefer the nicked DNA; however, this protein was cross-linked with approximately equal efficiency by single-stranded and double-stranded DNA containing a bulky substituent inside the strand. XPA seems to be sensitive not only to the structure of DNA double helix, but also to a bulky group incorporated into DNA. The mechanism of damage recognition in the process of nucleotide excision repair is discussed.     

Strand-specific binding of RPA and XPA to damaged duplex DNA

The nucleotide excision repair (NER) pathway is a major pathway used to repair bulky adduct DNA damage. Two proteins, xeroderma pigmentosum group A protein (XPA) and replication protein A (RPA), have been implicated in the role of DNA damage recognition in the NER pathway. The particular manner in which these two damage recognition proteins align themselves with respect to a damaged DNA site was assessed using photoreactive base analogues within specific DNA substrates to allow site-specific cross-linking of the damage recognition proteins. Results of these studies demonstrate that both RPA and XPA are in close proximity to the adduct as measured by cross-linking of each protein directly to the platinum moiety. Additional studies demonstrate that XPA contacts both the damaged and undamaged strands of the duplex DNA. Direct evidence is presented demonstrating preferential binding of RPA to the undamaged strand of a duplex damaged DNA molecule.     

Enhanced recA protein binding to Z DNA represents a kinetic perturbation of a general duplex DNA binding pathway

recA protein binding to duplex DNA is enhanced when a B form DNA substrate is replaced with a left-handed Z form helix. This represents a kinetic rather than an equilibrium effect. Binding to Z DNA is much faster than binding to B DNA. In other respects, binding to the two DNA forms is quite similar. recA protein binds to B or Z DNA with a stoichiometry of 1 monomer/4 base pairs. The final protein filament exhibits a right-handed helical structure when either B or Z form DNAs are bound. There are only two evident differences: the kcat for ATP hydrolysis is reduced 3-4-fold when Z DNA is bound, and recA binding at equilibrium is less stable on Z DNA than on B DNA. At steady state, the binding favors B DNA in competition experiments. The results indicate that Z DNA binding by recA protein follows the same pathway as for recA binding to B DNA, but that the nucleation step is faster on the Z form helix.     

Characterization of conformational features of DNA heteroduplexes containing aldehydic abasic sites

The DNA duplexes shown below, with D indicating deoxyribose aldehyde absic sites and numbering from 5' to 3', have been investigated by NMR. The 31P and 31P-1H correlation data indicate [formula: see text] that the backbones of these duplex DNAs are regular. One- and two-dimensional 1H NMR data indicate that the duplexes are right-handed and B-form. Conformational changes due to the presence of the abasic site extend to the two base pairs adjacent to the lesion site with the local conformation of the DNA being dependent on whether the abasic site is in the alpha or beta configuration. The aromatic base of residue A17 in the position opposite the abasic site is predominantly stacked in the helix as is G17 in the analogous sample. Imino lifetimes of the AT base pairs are much longer in samples with an abasic site than in those containing a Watson-Crick base pair. The conformational and dynamical properties of the duplex DNAs containing the naturally occurring aldehyde abasic site are different from those of duplex DNAs containing a variety of analogues of the abasic site.     

End invasion of peptide nucleic acids (PNAs) with mixed-base composition into linear DNA duplexes

Peptide nucleic acid (PNA) is a synthetic DNA mimic with valuable properties and a rapidly growing scope of applications. With the exception of recently introduced pseudocomplementary PNAs, binding of common PNA oligomers to target sites located inside linear double-stranded DNAs (dsDNAs) is essentially restricted to homopurine–homopyrimidine sequence motifs, which significantly hampers some of the PNA applications. Here, we suggest an approach to bypass this limitation of common PNAs. We demonstrate that PNA with mixed composition of ordinary nucleobases is capable of sequence-specific targeting of complementary dsDNA sites if they are located at the very termini of DNA duplex. We then show that such targeting makes it possible to perform capturing of designated dsDNA fragments via the DNA-bound biotinylated PNA as well as to signal the presence of a specific dsDNA sequence, in the case a PNA beacon is employed. We also examine the PNA–DNA conjugate and prove that it can initiate the primer-extension reaction starting from the duplex DNA termini when a DNA polymerase with the strand-displacement ability is used. We thus conclude that recognition of duplex DNA by mixed-base PNAs via the end invasion has a promising potential for site-specific and sequence-unrestricted DNA manipulation and detection.     

Does the specific recognition of DNA by the restriction endonuclease EcoRI involve a linear diffusion step? Investigation of the processivity of the EcoRI endonuclease.

The time course of the EcoRI endonuclease catalysed cleavage of three substrates, two plasmid DNAs and one oligonucleotide, each with two EcoRI sites, was measured. The two plasmid DNAs with the EcoRI sites 318 and 96 base pairs apart are cut in a distributive fashion, while the oligonucleotide with the EcoRI sites 8 base pairs apart is cut in a partially processive manner. It is concluded that a linear diffusion of the EcoRI endonuclease on its substrate across long stretches of DNA is not likely to be operative during the recognition process. Microscopic dissociation-reassociation processes, however, increase the probability of the enzyme to attack further sites located in the immediate vicinity of a given site.