Differential Hydration Thermodynamics of Stereoisomeric DNA−Benzo[a]pyrene Adducts Derived from Diol Epoxide Enantiomers with Different Tumorigenic Potentials

Unfolding and Targeting Thermodynamics of a DNA Intramolecular Complex with Joined Triplex-Duplex Domains

Our laboratory is interested in developing methods that can be used for the control of gene expression. In this work, we are investigating the reaction of an intramolecular complex containing a triplex-duplex junction with partially complementary strands. We used a combination of isothermal titration calorimetry (ITC), differential scanning calorimetry (DSC), and spectroscopy techniques to determine standard thermodynamic profiles for these targeting reactions. Specifically, we have designed single strands to target one loop (CTTTC) or two loops (CTTTC and GCAA) of this complex. Both reactions yielded exothermic enthalpies of -66.3 and -82.8 kcal/mol by ITC, in excellent agreement with the reaction enthalpies of -72.7 and -88.7 kcal/mol, respectively, obtained from DSC Hess cycles. The favorable heat contributions result from the formation of base-pair stacks involving mainly the unpaired bases of the loops. This shows that each complementary strand is able to invade and disrupt the secondary structure. The simultaneous targeting of two loops yielded a more favorable reaction free energy, by approximately -8 kcal/mol, which corresponds to the formation of roughly four base-pair stacks involving the unpaired bases of the 5'-GCAA loop. The main conclusion is that the targeting of loops with a large number of unpaired bases results in a more favorable reaction free energy.

Influence of PNA containing 8-aza-7-deazaadenine on structure stability and binding affinity of PNA·DNA duplex: insights from thermodynamics, counter ion, hydration and molecular dynamics analysis

This paper describes the synthesis of a novel 8-aza-7-deazapurin-2,6-diamine (DPP)-containing peptide nucleic acid (PNA) monomer and Boc protecting group-based oligomerization of PNA, replacing adenine (A) with DPP monomers in the PNA strand. The PNA oligomers were synthesized against the biologically relevant SV40 promoter region (2494-AATTTTTTTTATTTA-2508) of pEGFP-N3 plasmid. The DPP-PNA·DNA duplex showed enhanced stability as compared to normal duplex (A-PNA·DNA). The electronic distribution of DPP monomer suggested that DPP had better electron donor properties over 2,6-diamino purine. UV melting and thermodynamic analysis revealed that the PNA oligomer containing a diaminopyrazolo(3,4-d)pyrimidine moiety (DPP) stabilized the PNA·DNA hybrids compared to A-PNA·DNA. DPP-PNA·DNA duplex showed higher water activity (Δnw = 38.5) in comparison to A-PNA·DNA duplex (Δnw = 14.5). The 50 ns molecular dynamics simulations of PNA·DNA duplex containing DPP or unmodified nucleobase-A showed average H-bond distances in the DPP-dT base pair of 2.90 Å (OH-N bond) and 2.91 Å (NH-N bond), which were comparably shorter than in the A-dT base pair, in which the average distances were 3.18 Å (OH-N bond) and 2.97 Å (NH-N bond), and there was one additional H-bond in the DPP-dT base pair of around 2.98 Å (O2H-N2 bond), supporting the higher stability of DPP-PNA·DNA. The analysis of molecular dynamics simulation data showed that the system binding free energy increased at a rate of approximately -4.5 kcal mol(-1) per DPP base of the PNA·DNA duplex. In summary, increased thermal stability, stronger hydrogen bonding and more stable conformation in the DPP-PNA·DNA duplex make it a better candidate as antisense/antigene therapeutic agents.

Thermodynamic profiles and nuclear magnetic resonance studies of oligonucleotide duplexes containing single diastereomeric spiroiminodihydantoin lesions

The spiroiminodihydantoins (Sp) are highly mutagenic oxidation products of guanine and 8-oxo-7,8-dihydroguanine in DNA. The Sp lesions have recently been detected in the liver and colon of mice infected with Helicobacter hepaticus that induces inflammation and the development of liver and colon cancers in murine model systems [Mangerich, A., et al. (2012) Proc. Natl. Acad. Sci. U.S.A. 109, E1820-E1829]. The impact of Sp lesions on the thermodynamic characteristics and the effects of the diastereomeric Sp-R and Sp-S lesions on the conformational features of double-stranded 11-mer oligonucleotide duplexes have been studied by a combination of microcalorimetric methods, analysis of DNA melting curves, and two-dimensional nuclear magnetic resonance methods. The nonplanar, propeller-like shapes of the Sp residues strongly diminish the extent of local base stacking interactions that destabilize the DNA duplexes characterized by unfavorable enthalpy contributions. Relative to that of an unmodified duplex, the thermally induced unfolding of the duplexes with centrally positioned Sp-R and Sp-S lesions into single strands is accompanied by a smaller release of cationic counterions (Δn(Na⁺) = 0.6 mol of Na⁺/mol of duplex) and water molecules (Δn(w) = 17 mol of H₂O/mol of duplex). The unfolding parameters are similar for the Sp-R and Sp-S lesions, although their orientations in the duplexes are different. The structural disturbances radiate one base pair beyond the flanking C:G pair, although Watson-Crick hydrogen bonding is maintained at all flanking base pairs. The observed relatively strong destabilization of B-form DNA by the physically small Sp lesions is expected to have a significant impact on the processing of these lesions in biological environments.

Incorporation of 3-aminobenzanthrone into 2'-deoxyoligonucleotides and its impact on duplex stability

3-Nitrobenzanthrone (3NBA), an environmental pollutant and potent mutagen, causes DNA damage via the reaction of its metabolically activated form with the exocyclic amino groups of purines and the C-8 position of guanine. The present work describes a synthetic approach to the preparation of oligomeric 2′-deoxyribonucleotides containing a 2-(2′-deoxyguanosin-N²-yl)-3-aminobenzanthrone moiety, one of the major DNA adducts found in tissues of living organisms exposed to 3NBA. The NMR spectra indicate that the damaged oligodeoxyribonucleotide is capable of forming a regular double helical structure with the polyaromatic moiety assuming a single conformation at room temperature; the spectra suggest that the 3ABA moiety resides in the duplex minor groove pointing toward the 5′-end of the modified strand. Thermodynamic studies show that the dG(N²)-3ABA lesion has a stabilizing effect on the damaged duplex, a fact that correlates well with the long persistence of this damage in living organisms.

Characterization of DNA with an 8-oxoguanine modification

The oxidation of DNA resulting from reactive oxygen species generated during aerobic respiration is a major cause of genetic damage that, if not repaired, can lead to mutations and potentially an increase in the incidence of cancer and aging. A major oxidation product generated in cells is 8-oxoguanine (oxoG), which is removed from the nucleotide pool by the enzymatic hydrolysis of 8-oxo-2′-deoxyguanosine triphosphate and from genomic DNA by 8-oxoguanine-DNA glycosylase. Finding and repairing oxoG in the midst of a large excess of unmodified DNA requires a combination of rapid scanning of the DNA for the lesion followed by specific excision of the damaged base. The repair of oxoG involves flipping the lesion out of the DNA stack and into the active site of the 8-oxoguanine-DNA glycosylase. This would suggest that thermodynamic stability, in terms of the rate for local denaturation, could play a role in lesion recognition. While prior X-ray crystal and NMR structures show that DNA with oxoG lesions appears virtually identical to the corresponding unmodified duplex, thermodynamic studies indicate that oxoG has a destabilizing influence. Our studies show that oxoG destabilizes DNA (ΔΔG of 2–8 kcal mol⁻¹ over a 16–116 mM NaCl range) due to a significant reduction in the enthalpy term. The presence of oxoG has a profound effect on the level and nature of DNA hydration indicating that the environment around an oxoG•C is fundamentally different than that found at G•C. The temperature-dependent imino proton NMR spectrum of oxoG modified DNA confirms the destabilization of the oxoG•C pairing and those base pairs that are 5′ of the lesion. The instability of the oxoG modification is attributed to changes in the hydrophilicity of the base and its impact on major groove cation binding.

A thermodynamic approach for the targeting of nucleic acid structures using their complementary single strands

The main focus of our investigations is to further our understanding of the physicochemical properties of nucleic acid structures. We report on a thermodynamic approach to study the reaction of a variety of intramolecular nucleic acid structures with their respective complementary strands. Specifically, we have used a combination of isothermal titration (ITC) and differential scanning calorimetry (DSC) and spectroscopy techniques to determine standard thermodynamic profiles for the reaction of a triplex, G-quadruplex, hairpin loops, pseudoknot, and three-arm junctions with their complementary strands. Reaction enthalpies are measured directly in ITC titrations, and compared with those obtained indirectly from Hess cycles using DSC unfolding data. All reactions investigated yielded favorable free energy contributions, indicating that each single strand is able to invade and disrupt the corresponding intramolecular DNA structure. These favorable free energy terms are enthalpy-driven, resulting from a favorable compensation of exothermic contributions due to the formation of additional base-pair stacks in the duplex product, and endothermic contributions, from the disruption of base stacking contributions of the reactant single strands. The overall results provide a thermodynamic approach that can be used in the targeting of nucleic acids, especially the secondary structures formed by mRNA, with oligonucleotides for the control of gene expression.

Experiment and prediction: a productive symbiosis in studies on the thermodynamics of DNA oligomers

Recently, we reported the kinetics of hybridization of cDNA dodecamers (Carrillo-Nava, E., Mejía-Radillo, Y., and Hinz, H.-J. Biochemistry 2008, 47, 13153-13157). In this study, we provide the thermodynamic reaction parameters of those dodecamers as well as a comparison with parameters for 24-mers designed from two identical dodecamers in tandem arrangement. The thermodynamic properties were determined by isothermal titration calorimetry (ITC), differential scanning microcalorimetry (DSC), and UV melting studies. On the basis of the results from our kinetic studies, fitting algorithms of DSC and UV melting profiles employed the two-state assumption for the duplex to a single strand dissociation reaction. The formation of both 12-mer and 24-mer duplexes is strongly enthalpy driven at all temperatures. At identical temperatures, the hybridization enthalpy of the 24-mer is within error limits twice that of the 12-mer. Duplex formation is always associated with a significant negative heat capacity change, ΔC(p), which, on a mass basis, is comparable to that observed for protein folding. Only a small part of the favorable reaction enthalpy appears as a standard Gibbs free energy change due to large compensating negative entropy changes linked to duplex formation. On the basis of the results of the present studies, it appears to be absolutely essential for a proper analysis of thermodynamic parameters of oligonucleotide hybridization reactions to combine low temperature ITC measurements of binding enthalpies with DSC and UV melting studies to obtain an accurate assessment of standard Gibbs energy changes or, equivalently, hybridization constants over a broad temperature range. The experimental thermodynamic parameters were compared with theoretical estimates based on nearest-neighbor approximations employing temperature-independent enthalpies. Good agreement between experimental and predicted ΔG° values is observed at ambient temperatures (20-30 °C), as long as helix formation is associated with small molar heat capacity changes. If the experimental ΔC(p) values determined by ITC are taken into account, significant deviations occur.

Energetic and hydration contributions of the removal of methyl groups from thymine to form uracil in G-quadruplexes

A combination of spectroscopic and calorimetric techniques is used to investigate the unfolding of two G-quadruplexes: d(G2U2G2UGUG2U2G2), G2-U, and d(G2T2G2TGTG2T2G2), G2. The comparisons of their thermodynamic data allow us to elucidate the role of methylation on the energetic and hydration properties accompanying their stable formation. The favorable formation of each G-quadruplex results from the characteristic enthalpy-entropy compensation, uptake of ions, and release of water molecules. The loops of G2-U and G2 contribute favorably to their formation, and the absence of methyl groups stabilizes the G-quadruplex. The unfolding of G2-U produces a larger DeltaV, indicating a difference in the hydration states of the two oligonucleotides, while the opposite signs between DeltaDeltaG with the DeltaDeltaV suggest that the differential hydration reflects structural, or hydrophobic, water is involved in the unfolding of G-quadruplexes.

Thermodynamic contributions of the reactions of DNA intramolecular structures with their complementary strands

One focus of our research is to further our understanding of the physico-chemical properties of unusual DNA structures and their interaction with complementary oligonucleotides. We have investigated three types of reactions involving the interaction of intramolecular DNA complexes with their complementary single strands of varied length. Specifically, we have used a combination of isothermal titration (ITC) and differential scanning (DSC) calorimetry and spectroscopy techniques to determine standard thermodynamic profiles for the reaction of an i-motif, G-quadruplex, and triplex with their complementary strands. The enthalpies for each reaction are measured directly in ITC titrations and compared with those obtained indirectly from Hess cycles using DSC unfolding data. All reactions investigated yielded favorable free energy contributions, indicating that each single strand is able to invade and disrupt the corresponding intramolecular DNA complex. These favorable free energy terms are enthalpy driven, which result from a compensation of exothermic contributions, due to the formation of additional base-pair stacks (or base-triplet stacks) in the duplex product (or triplex product), immobilization of electrostricted water by the base-pair and base-triplet stacks, and the removal of structural water from the reactant single strands; and endothermic contributions from the disruption of base-base stacking interactions of the reactant single strands. This investigation of nucleic acid reactions has provided new methodology, based on physico-chemical principles, to determine the molecular forces involved in the interactions between DNA nucleic acid structures. This methodology may be used in targeting reactions for the control of gene expression.

Thermodynamics of DNA-RNA heteroduplex formation: effects of locked nucleic acid nucleotides incorporated into the DNA strand

A locked nucleic acid (LNA) monomer is a conformationally restricted nucleotide analogue exhibiting enhanced hybridization efficiency toward complementary strand. The potential of LNA-based oligonucleotides has been sought to improve the selectivity and specificity of probe sets employed in detection and specific targeting of nucleic acids. We have evaluated the influence of "locked nucleic acid" residues on hybridization thermodynamics, counterions and hydration of DNA.RNA heteroduplex using spectroscopic and calorimetric techniques. One to three LNA substitutions have been introduced either at the adenine (5'-AGCACCAG) or thymine (5'-TGCTCCTG) residues of the DNA strand. A complete thermodynamic profile for heteroduplex formation suggested that LNA-induced stabilization results from a favorable increase in the enthalpy of hybridization that compensates for the unfavorable entropy change. Analysis of differential scanning calorimetry data indicated a nonzero heat capacity change, DeltaCp, accompanying the heteroduplex formation. Isothermal titration calorimetry measurements indicated an increase in binding affinity of the two strands as the LNA content of the heteroduplex is increased. Overall our result demonstrated that the effect of LNA-substitution at the thymine residue is more pronounced compared to the adenine residue. Furthermore, optical melting studies showed that, compared to an unmodified duplex, the formation of LNA-modified duplex is accompanied by a higher uptake of counterions and a lower uptake of water molecules. Our result, thus, presents a preliminary attempt toward the characterization of hybridization thermodynamics of the LNA-based probe-target sets, which will in turn aid in the selection of optimal conditions for hybridization experiments, and evaluation of the minimum probe-length required for hybridization and cloning experiments.

Novel biomineral-binding cyclodextrins for controlled drug delivery in the oral cavity

A biomineral-binding alendronate-beta-cyclodextrin conjugate (ALN-beta-CD, Fig. 1) was developed as a novel drug delivery system. "Click" chemistry was used in conjugation of alendronate (ALN) to beta-cyclodextrin (beta-CD). The delivery system shows very strong binding to hydroxyapatite (HA, main component of tooth enamel). Its ability in forming molecular inclusion complex with dexamethsone (Dex, model drug) was investigated independently with phase solubility experiments, isothermal titration calorimetry (ITC), Job plot and (1)H NMR. The stoichiometry of ALN-beta-CD/Dex molecular complex was determined as 1:1, and the binding constant of the complex obtained from ITC study is 3.8 x 10(3) M(-1), which is similar to the binding constant of beta-CD/Dex. In vitro data indicate that the ALN-beta-CD/Dex complex bound to HA could gradually release Dex upon repeated extraction with phosphate buffer saline (PBS). This novel drug delivery system may have great potential in improving treatment of diseases in the oral cavity.

The human DNA repair factor XPC-HR23B distinguishes stereoisomeric benzo[a]pyrenyl-DNA lesions

Benzo[a]pyrene (B[a]P), a known environmental pollutant and tobacco smoke carcinogen, is metabolically activated to highly tumorigenic B[a]P diol epoxide derivatives that predominantly form N(2)-guanine adducts in cellular DNA. Although nucleotide excision repair (NER) is an important cellular defense mechanism, the molecular basis of recognition of these bulky lesions is poorly understood. In order to investigate the effects of DNA adduct structure on NER, three stereoisomeric and conformationally different B[a]P-N(2)-dG lesions were site specifically incorporated into identical 135-mer duplexes and their response to purified NER factors was investigated. Using a permanganate footprinting assay, the NER lesion recognition factor XPC/HR23B exhibits, in each case, remarkably different patterns of helix opening that is also markedly distinct in the case of an intra-strand crosslinked cisplatin adduct. The different extents of helix distortions, as well as differences in the overall binding of XPC/HR23B to double-stranded DNA containing either of the three stereoisomeric B[a]P-N(2)-dG lesions, are correlated with dual incisions catalyzed by a reconstituted incision system of six purified NER factors, and by the full NER apparatus in cell-free nuclear extracts.

Thermodynamic, counterion, and hydration effects for the incorporation of locked nucleic acid nucleotides into DNA duplexes

A locked nucleic acid (LNA) monomer is a conformationally restricted nucleotide analogue with an extra 2'-O, 4'-C-methylene bridge added to the ribose ring. LNA-modified oligonucleotides are known to exhibit enhanced hybridization affinity toward complementary DNA and RNA. In this work, we have evaluated the hybridization thermodynamics of a series of LNA-substituted DNA octamers, modified to various extents by one to three LNA substitutions, introduced at either adenine (5'-AGCACCAG) or thymine (5'-TGCTCCTG) nucleotides. To understand the energetics, counterion effects, and the hydration contribution of the incorporation of LNA modification, a combination of spectroscopic and calorimetric techniques was used. The CD spectra of the corresponding duplexes showed that the modified duplexes adopt an A-type conformation. UV and DSC melting studies revealed that each type of duplex unfolds in a two-state transition. A complete thermodynamic profile at 5 degrees C indicated that the net effect of modification on thermodynamic parameters might be positional and that the neighboring bases flanking the modification might influence the favorable formation of the modified duplexes. Furthermore, relative to the formation of the unmodified reference duplexes, the formation of modified duplexes is accompanied by a higher uptake of counterions and a lower uptake of water molecules.

Simulating structural and thermodynamic properties of carcinogen-damaged DNA

A pair of stereoisomeric covalent adducts to guanine in double-stranded DNA, derived from the reaction of mutagenic and tumorigenic metabolites of benzo[a]pyrene, have been well characterized structurally and thermodynamically. Both high-resolution NMR solution structures and an array of thermodynamic data are available for these 10S (+)- and 10R (-)-trans-anti -[BP]-N(2)-dG adducts in double-stranded deoxyoligonucleotides. The availability of experimentally well-characterized duplexes containing these two stereoisomeric guanine adducts provides an opportunity for evaluating the molecular mechanics Poisson-Boltzmann surface area (MM-PBSA) method for computing thermodynamic properties from molecular dynamics ensembles. We have carried out 3-ns molecular dynamics simulations, using NMR solution structures as the starting models for the 10S (+)- and 10R (-)-trans-anti-dG adducts in a DNA duplex 11-mer using AMBER 6.0. We employed the MM-PBSA method to compute the free energies, enthalpies, and entropies of the two adducts. Our complete thermodynamic analysis agrees quite well with the full experimental thermodynamic characterization of these adducts, showing essentially equal stabilities of the two adducts. We also calculated the nuclear Overhauser effect (NOE) distances from the molecular dynamics trajectories, and compared them against the experimental NMR-derived NOE distances. Our results showed that the simulated structures are in good agreement with the NMR experimental NOE data. Furthermore, the molecular dynamics simulations provided new structural and biological insights. Specifically, the puzzling observation that the BP aromatic ring system in the 10S (+)-trans-anti-dG adduct is more exposed to the aqueous solvent than the 10R (-)-trans-anti-dG adduct, is rationalized in terms of the adduct structures. The structural and thermodynamic features of these stereoisomeric adducts are also discussed in relation to their reported low susceptibilities to nucleotide excision repair.

Effect of cationic charge localization on DNA structure

DNA is normally considered to be a stiff rod-like molecule, but proteins and small molecules, which either equilibrium bind to, or covalent bond with, DNA, can overcome the barrier(s) to non-linearity by changing the local hydrophobic and electrostatic environment at specific DNA sequences. The deformation of DNA by proteins has been shown to be a critical event in transcriptional regulation. In this review, we have focused on how the introduction of cationic charge, and its location, can affect DNA structure. To study the effect of charge, we have used DNA modified with 3-aminopropyl substitutions at the 5-position of deoxyuracil that mimic basic lysine-like sidechains, and which place the cationic charge in the major groove. Previous gel mobility studies with these sidechains have shown that they bend DNA. The location of the cationic sidechains and how they bend DNA is discussed.

Thermodynamic and structural factors in the removal of bulky DNA adducts by the nucleotide excision repair machinery

The function of the human nucleotide excision repair (NER) apparatus is to remove bulky adducts from damaged DNA. In an effort to gain insights into the molecular mechanisms involved in the recognition and excision of bulky lesions, we investigated a series of site specifically modified oligonucleotides containing single, well-defined polycyclic aromatic hydrocarbon (PAH) diol epoxide-adenine adducts. Covalent adducts derived from the bay region PAH, benzo[a]pyrene, are removed by human NER enzymes in vitro. In contrast, the stereochemically analogous N(6)-dA adducts derived from the topologically different fjord region PAH, benzo[c]phenanthrene, are resistant to repair. The evasion of DNA repair may play a role in the observed higher tumorigenicity of the fjord region PAH diol epoxides. We are elucidating the structural and thermodynamic features of these adducts that may underlie their marked distinction in biologic function, employing high-resolution nuclear magnetic resonance studies, measurements of thermal stabilities of the PAH diol epoxide-modified oligonucleotide duplexes, and molecular dynamics simulations with free energy calculations. Our combined findings suggest that differences in the thermodynamic properties and thermal stabilities are associated with differences in distortions to the DNA induced by the lesions. These structural effects correlate with the differential NER susceptibilities and stem from the intrinsically distinct shapes of the fjord and bay region PAH diol epoxide-N(6)-adenine adducts.

DNA oligonucleotide duplexes containing intramolecular platinated cross-links: energetics, hydration, sequence, and ionic effects

The anticancer activity of cisplatin arises from its ability to bind covalently to DNA, forming primarily intrastrand cross-links to adjacent purine residues; the most common adducts involve d(GpG) (65%) and d(ApG) (25%) intrastrand cross-links. The incorporation of these platinum adducts in a B-DNA helix induces local distortions, causing bending and unwinding of the DNA. In this work, we used temperature-dependent UV spectroscopy to investigate the unfolding thermodynamics, and associated ionic effects, of two sets of DNA decamer duplexes containing either cis-[Pt(NH(3))(2)[d(GpG]] or cis-[Pt(NH(3))(2) [d(ApG]] cross-links, and their corresponding unmodified duplexes. The platinated duplexes are less stable and unfold with lower T(M)s (and Delta G degrees s) in enthalpy-driven reactions, which indicates a loss of favorable base-pair stacking interactions. The folding thermodynamics and hydration effects for the first set of decamers containing the d(GpG) cross-link was investigated by a combination of titration calorimetry, density, and ultrasound techniques. The hydration parameters showed an uptake of structural water by the platinated duplex and a release of electrostricted water by the control duplex. Relative to the unmodified duplex, the folding of the platinated duplex at 20 degrees C yielded a positive Delta Delta G degrees term [and positive Delta Delta H-Delta(T Delta S) compensation] and a negative differential volume change. The opposite signs of the Delta Delta G degrees and Delta Delta V terms confirmed its uptake of structural water. Further, solvent-accessible surface areas calculations for a similar pair of dodecamer duplexes indicated that the modified duplex has a 503 oeA(2) higher polar and nonpolar surface area that is exposed to the solvent. Therefore, the incorporation of a platinum adduct in duplex DNA disrupts favorable base-pair stacking interactions, yielding a greater exposure of aromatic bases to the solvent, which in turn immobilizes structural water. The overall results correlate nicely with the results reported in the available structural data of nuclear magnetic resonance solution studies.

Energetic and conformational contributions to the stability of Okazaki fragments

A combination of spectroscopic and calorimetric techniques was used to determine complete thermodynamic profiles accompanying the folding of a model Okazaki fragment with sequence 5'-r(gagga)d(ATCTTTG)-3'/5'-d(CAAAGATTCCTC)-3' and control DNA (with and without thymidine substitutions for uridine), RNA, and hybrid duplexes. Circular dichroism spectroscopy indicated that all DNA duplexes are in the B conformation, the RNA and hybrid duplexes are in the A conformation, and the Okazaki fragment exhibits a spectrum between the A and B conformations. Ultraviolet and differential scanning calorimetry melting experiments reveal that all duplexes unfold in two-state transitions with thermal stabilities that follow the order RNA > OKA > DNA (with thymidines) > hybrids > DNA (with uridines). The dependence of the transition temperature on salt concentration yielded counterion releases in the following order: DNA (with thymidines) > RNA > DNA (with uridines) > OKA > hybrids. Thus, Okazaki fragments have a conformation and charge density between those of its components DNA and hybrid segments. However, the presence of the RNA-DNA/DNA junction confers on them higher stabilities than their component hybrid and DNA segments. The binding of intercalators to an Okazaki hairpin of sequence 5'-r(gc)d(GCU5GCGC)-3' and to its control DNA hairpin has also been studied. The results show that the binding of intercalators to Okazaki fragments is accompanied with higher heats and lower binding affinities, compared with DNA duplexes. This suggests that the presence of an RNA/DNA junction yields a larger surface contact to interact with the phenanthroline ring of the intercalators, which may lead to a larger disruption of the flexible flanking bases of the junction. The overall results suggest that the presence of this junction stabilizes Okazaki fragments and provides a structural feature that can be exploited in the design of drugs to specifically target these molecules.

Synthesis and characterization of site-specific and stereoisomeric fjord dibenzo[a,l]pyrene diol epoxide-N(6)-adenine adducts: unusual thermal stabilization of modified DNA duplexes

The fjord polycyclic aromatic hydrocarbon compound dibenzo[a,l]pyrene (DB[a,l]P) is significantly more tumorigenic than the bay region benzo[a]pyrene in animal model systems. The molecular origins of the unusually strong genotoxic properties of DB[a,l]P and its fjord region diol epoxide metabolites are of great interest and are believed to be related to the structural characteristics of the DNA adducts formed. Site-specifically modified oligonucleotides were prepared by reacting the single adenine residue in 5'-d(CTCTCACTTCC) (I) with the racemic fjord diol epoxide r11,t12-dihydrodiol-t13,14-epoxide-11,12,13,14-tetrahydrodibenzo[a,l]pyrene (anti-DB[a,l]PDE) in aqueous solutions. Four different oligonucleotides I with the single adenosine residues involving a covalent bond between the C14 position of DB[a,l]PDE and N(6)-dA are identified and purified. The CD spectra of the mononucleotide adducts are similar to those of Li et al. [Li et al. (1999) Chem. Res. Toxicol. 12, 758] who characterized DB[a,l]PDE-N(6)-dA adducts by a combination of CD and NMR methods. The stereochemical properties of each of the four DB[a,l]PDE-modified oligonucleotides were assigned on the basis of a combination of empirical CD rules and other approaches and differ from those of Li et al. The thermal melting points, T(m), of the unmodified duplex of I with its complementary strand (IC), T(m) = 43.8 +/- 0.5 degrees C, were compared with the same duplexes containing stereoisomeric anti-DB[a,l]PDE-N(6)-dA lesions. The T(m) of duplexes I.IC containing lesions with R absolute configurations at C14 of the DB[a,l]PDE residues are greater by 6-8 degrees C, while those with S configuration are lower by 6-10 degrees C. Similar effects are observed with adducts in the same sequence context derived from the fjord PAH anti-diol epoxides of benzo[g]chrysene, while duplexes containing lesions derived from benzo[c]phenanthrene diol epoxides with 1R and 1S configurations exhibit unchanged T(m) values. In contrast, the T(m) values of duplexes with lesions derived from the bay region benzo[a]pyrene diol epoxides (B[a]PDE) in the same sequence are lower by 12 degrees (10R adducts) and by 19 degrees (10S adducts). The greater thermal stabilities of duplexes with fjord PAH-N(6)-dA lesions relative to those with bay region B[a]PDE-N(6)-dA adducts, are correlated with lower susceptibilities of excision by human nucleotide excision repair enzymes [Buterin et al. (2000) Cancer Res. 60, 1849]. The implications of these relationships are discussed in terms of present knowledge of the conformations of fjord and bay region PAH diol epoxide-N(6)-dA lesions in double stranded DNA.

Effect of mismatched complementary strands and 5'-change in sequence context on the thermodynamics and structure of benzo[a]pyrene-modified oligonucleotides

Benzo[a]pyrene (B[a]P) is a well-studied environmental carcinogen that when activated can react with DNA to form four major adducts: (+)-trans-, (-)-trans-, (+)-cis-, and (-)-cis-anti-B[a]P-dG. In this study, two oligonucleotides (5'-dCCATT-GB[a]P-CTACC-3' and 5'-dCCATC-GB[a]P-CTACC-3') were prepared, each containing the four isomeric adducts, and these were hybridized to either complementary sequences or to sequences containing an A, G, or T opposite the adducted guanine. Thermal melting curves, CD, and UV spectra of each duplex were measured and compared with the unmodified counterpart. The raw and relative thermodynamic measurements were then compared which indicated that differences occur that are both adduct and sequence dependent. These differences were next compared with the in vitro DNA polymerase incorporation data and were found to be strikingly correlated. Most significantly, for all four B[a]P isomers a mismatch of an A across from the adduct resulted in the least amount of relative destabilization, while the Watson-Crick complement C showed the most; in vitro studies showed that A is the preferred base incorporated across from each isomer, while C was incorporated least often. This observed correlation suggests that one factor contributing to misincorporation at an adduct site is the thermodynamic stability of the incorporated base. Structurally, the effect of sequence context and mismatched complementary strands were also compared, suggesting that all adducts tend to intercalate within the helix when they are complemented with a mismatched complementary strand. In addition, the level of this intercalation seems to be both sequence and stereoisomer dependent.

Thermodynamics of dT--dT base pair mismatching in linear DNA duplexes and three-arm DNA junctions

We have used a combination of magnetic-suspension densimetry and calorimetry to derive complete thermodynamic profiles, including volume changes, for the formation of linear DNA duplexes and three-arm branched DNA junctions, from their component strands, with and without dT-dT mismatches. The formation of each type of complex at 20 degrees C is accompanied by a favorable free energy, with a favorable enthalpy term partially compensated by an unfavorable entropy. Formation is associated also with net uptake of water molecules. Using the formation of the fully-paired linear duplex or three-arm junction as reference states, we can establish a thermodynamic cycle in which the contribution of the single-strand species cancels. From this cycle, we determine that substitution of dA for dT has a differential free energy of deltadeltaG degrees of +2.4 kcal mol(-1) for mismatched duplex and +2.0 kcal mol(-1) (on the average) for the mismatched junction. These unfavorable differential free energies result from an unfavorable enthalpy, partially compensated by a favorable entropy, and a negative deltadeltaV. The free energies in the two cases have signs opposed to those of deltadeltaV, a situation that implicates hydration changes in creating the mismatch. When the deltadeltaV terms are normalized by the total number of base pairs involved, the immobilization of structural water molecules (and/or substitution of electrostricted for hydrophobic water molecules) is about 7 times greater for junctions than duplexes. This is consistent with more extensive hydrophobic hydration of branched DNA structures than of duplexes.