Perturbation of Hydrogen Bonds in the Adenine…Thymine Base Pair by Na+, Mg2+, Ca2+ and NH4 + Cations

Abstract

Perturbation of the hydrogen bonds in the adenine…thymine base pair by Na⁺, Mg²⁺, Ca²⁺ and NH₄ ⁺ cations has been investigated by means of ab initio SCF calculations with the STO-3G basis set. The geometry of adenine…thymine, as well as those of the perturbed pairs were optimized. Approach of any cation to thymine at 06 leads to destabilization of the adenine…thy mine pair; divalent cations (Mg²⁺, Ca²⁺) have a profound effect on the structure of the base pair. The approach of a cation to other available sites (thymine: O2, adenine N1 and N3) leads, on the other hand, to stabilization of the base pair. If a water molecule is placed between the cation and the base pair, the structure and stability of the base pair are changed only negligibly.     

Novel Hoogsteen-like Bases for Recognition of the C-G Base Pair by DNA Triplex Formation

Effective sequence-specific recognition of duplex DNA is possible by triplex formation with natural oligonucleotides via Hoogsteen H-bonding. However, triplex formation is in practice limited to pyrimidine oligonucleotides that bind duplex A-T or G-C base pair DNA sequences specifically at homopurine sites in the major groove as T·A-T and C⁺ ·G-C triplets. Here we report the successful modelling of novel unnatural nucleosides that recognize the C-G DNA base pair by Hoogsteen-like major groove interaction. These novel Hoogsteen nucleotides are examined within model A-type and B-type conformation triplex structures since the DNA triplex can be considered to incorporate A-type and/or B-type configurational properties. Using the same deoxyribose-phosphodiester and base-deoxyribose dihedral angle configuration, a triplet comprised of a C-G base pair and the novel Hoogsteen nucleotide, Y2, replaces the central T·A-T triplet in the triplex. The presence of any structural or energetic perturbations due to the central triplet in the energy-minimized triplex is assessed with respect to the unmodified energy minimized (T·A-T)₁₁ starting structures. Incorporation of this novel triplet into both A-type and B-type natural triplex structures provokes minimal change in the configuration of the central and adjacent triplets.     

Variable Temperature Infrared Spectroscopy of Cytosine-Guanine Base Pairs: Tautomerism Versus Polarization

Abstract

This report describes an infrared (IR) spectroscopic study of a model cytosine - guanine base pair. This base pair is part of a self-consistent experimental system based on lipophilic ribose derivatives of cytidine (C), guanosine (G) and O⁶-methylguanosine (O⁶MeG) that are soluble in non-aqueous, low dielectric solvents at appreciable concentrations. Previous experiments on this system have revealed different rotation dynamics for the amino bonds within the CG base pair, an observation that could be explained by the presence of rare tautomers (P.O. Lowdin, Reviews of Modern Physics 35, 724 (1963)), or by mutual polarization of the base pairs (L.D. Williams, N.G. Williams and B.R. Shaw, J. Am. Chem. Soc. 112, 829 (1990)). The IR spectra in the OH and NH stretching region indicate formation of hydrogen-bonded CG base pairs and self associates in 1,2-dichlorobenzene over a temperature range from 10 to 290K. Changes in the lineshapes and intensities of the IR bands with temperature correlate with phase transitions of the solvent but no evidence is seen for an OH stretching band that would indicate the formation of hydroxyl tautomers within base pairs. Similarly, the relative intensities of the C=O stretching bands of CG in cyclohexane solution remain constant over this same temperature range, confirming that within the base pair, the tautomeric states of the bases remain essentially unperturbed in the 2-amino/6-keto form of G and the 2-keto/4-amino form of C. The spectra of O⁶-MeG aid in the band assignments, since this molecule is frozen in an equivalent of the 2-amino/6-hydroxyl tautomer, but without the OH group and its associated stretching band. We conclude that the probability of tautomerism does not appear to be sufficient to explain the different rotation dynamics for the two amino bonds of the CG base pair. Rather it is argued that mutual polarization within the base pair, which would increase the bond order of the amino bond of C within the base pair, can explain the results without the formation of unconventional tautomers.     

Transition Metal Ligands as Novel DNA-Base Substitutes

Abstract

The base modified nucleoside dBP, carrying a non-hydrogen-bonding non-shape complementary base was incorporated into oligonucleotides (Brotschi, C.; Häberli, A.; Leumann C.J. Angew. Chem. Int. Ed. 2001, 40, 3012–3014). This base was designed to coordinate transition metal ions into well defined positions within a DNA double helix. Melting experiments revealed that the stability of a dBP: dBP base couple in a DNA duplex is similar to a dG: dC base pair even in the absence of transition metal ions. In the presence of transition metal ions, melting experiments revealed a decrease in duplex stability which is on a similar order for all metal ions (Mn²⁺, Cu²⁺, Zn²⁺, Ni²⁺) tested.     

Use of “Loss-of-Contact” Substitutions to Identify Residues Involved in an Amino Acid-Base Pair Contact: Effect of Substitution of Gln18 of Lac Repressor by Gly,Ser, and Leu

Abstract

A procedure to identify which base pair of lac operator (lacO) a suspected contacting amino acid of Lac repressor (LacR) interacts with is presented. The procedure is to eliminate the ability of the amino acid under study to contact DNA, and then to determine at which base pair—if any—specificity is eliminated. To implement this procedure, four sets of Escherichia coli K-12 strains have been constructed. These strains permit: (i) the substitution of a selected amino acid of LacR by, respectively, Gly, Ser, Leu, or Gln, and (ii) the analysis of the specificity of the resulting substituted LacR with respect to base pairs 5,6,7,8,9, and 10 of lacO. This procedure has been applied to Gln18 of LacR. The preliminary data indicate that LacR(Gln18?Gly) is unable to distinguish between the O⁺ base pair G:C and the O^c base pair T:A at position 7 of lacO (K_Doc/K_DO ⁺ = 0.93). In contrast, LacR(Glnl8?Gly) discriminates O⁺ from O^c by a factor of 13 to 23 at each other position. The same qualitative pattern of results was obtained with LacR(Glnl8?Ser) and LacR(Gln18?Leu). Therefore, I propose that Gln18 contacts base pair 7 of lacO. This proposal is consistent with the contact predicted in Ebright, R. in Protein Structure, Folding, and Design. D. Oxender ed., Alan R. Liss, New York (1985), in press.     

7-Deaza-2′-deoxyinosine: A Stable Nucleoside with the Ambiguous Base Pairing Properties of 2′-Deoxyinosine

Abstract

The base pairing ambiguity of 7-deaza-2′-deoxyinosine (c⁷I_d, 2) was studied and was found to be the same as that of 2′-deoxyinosine. The duplex stability decreases in the order [d(c⁷I-C) > d(c⁷I-A) > d(c⁷I-T) > d(c⁷I-G)]. Modified nucleosides were used to probe the various base pair motifs which were the same for dl and c⁷I_d. The 7-deazapurine nucleoside (2) is extremely stable against acid or base. As oligonucleotides can be prepared using phosphoramidite chemistry and DNA is accessible by enzymic polymerisation of the triphosphate of 2, the latter can be used as an universal nucleoside for the sequencing of DNA by chemical degradation and is otherwise a facile substitute of 2′-deoxyinosine when stability in acidic or alkaline solution is required.     

The Design and Synthesis of N 4-Anthraniloyl-2′-dC,the Improved Syntheses of N 4-Carbamoyl-and N4- Ureidocarbamoyl-2′-dC,Incorporation into Oligonucleotides and Triplex Formation Testing

Abstract

Three modified nucleosides were designed with the aim of achieving triplet formation with the CG base pair of duplex DNA. Direct anthraniloylation of 2′-deoxycytidine, using isatoic anhydride, afforded the novel N ⁴-anthraniloyl-2′-deoxycytidine. Much improved preparations of N ⁴-carbamoyl-2′-deoxycytidine and of N ⁴-ureidocarbonyl-2′-deoxycytidine were accomplished. The modified nucleosides were incorporated into oligonucleotides. Thermal denaturation studies and gel mobility shift analysis suggest that these nucleosides do not form base triplets with any of the four base pairs of DNA.     

Thermodynamic and structural properties of the specific binding between Ag ion and C:C mismatched base pair in duplex DNA to form C–Ag–C metal-mediated base pair

Metal ion-nucleic acid interactions have attracted considerable interest for their involvement in structure formation and catalytic activity of nucleic acids. Although interactions between metal ion and mismatched base pair duplex are important to understand mechanism of gene mutations related to heavy metal ions, they have not been well-characterized. We recently found that the Ag⁺ ion stabilized a C:C mismatched base pair duplex DNA. A C–Ag–C metal-mediated base pair was supposed to be formed by the binding between the Ag⁺ ion and the C:C mismatched base pair to stabilize the duplex. Here, we examined specificity, thermodynamics and structure of possible C–Ag–C metal-mediated base pair. UV melting indicated that only the duplex with the C:C mismatched base pair, and not of the duplexes with the perfectly matched and other mismatched base pairs, was specifically stabilized on adding the Ag⁺ ion. Isothermal titration calorimetry demonstrated that the Ag⁺ ion specifically bound with the C:C base pair at 1:1 molar ratio with a binding constant of 10⁶ M⁻¹, which was significantly larger than those for nonspecific metal ion-DNA interactions. Electrospray ionization mass spectrometry also supported the specific 1:1 binding between the Ag⁺ ion and the C:C base pair. Circular dichroism spectroscopy and NMR revealed that the Ag⁺ ion may bind with the N3 positions of the C:C base pair without distorting the higher-order structure of the duplex. We conclude that the specific formation of C–Ag–C base pair with large binding affinity would provide a binding mode of metal ion-DNA interactions, similar to that of the previously reported T-Hg-T base pair. The C–Ag–C base pair may be useful not only for understanding of molecular mechanism of gene mutations related to heavy metal ions but also for wide variety of potential applications of metal-mediated base pairs in various fields, such as material, life and environmental sciences.     

Fluorescence Properties and Base Pair Stability of Oligonucleotides Containing 8-Aza-7-deaza-2′-deoxyisoinosine or 2′-Deoxyisoinosine

Abstract

The fluorescence and the base pairing properties of 8-aza-7-deaza-2′-deoxyisoinosine (1) are described and compared with those of 2′-deoxyisoinosine (2). The corresponding phosphoramidites (11,12) are synthesized using the diphenyl-carbamoyl (DPC) residue for the 2-oxo group protection. The nucleosides 1 and 2 base pair with 2′-deoxy-5-methylisocytidine in DNA duplexes with antiparallel chain orientation and with 2′-deoxycytidine in a parallel DNA. These base pairs are less stable than the canonical dA-dT pair and that of 2′-deoxyinosine (4) with 2′-deoxycytidine. The fluorescence of the nucleosides 1 and 2 is quenched (～95%) in duplex DNA. The residual fluorescence is used to determine the T_m-values, which are found to be the same as determined UV-spectrophotometrically.     

Nonplanar DNA Base Pairs

Abstract

Three-dimensional structures of a representative set of more than 30 hydrogen-bonded nucleic acids base pairs have been studied by reliable ab initio quantum mechanical methods. We show that many hydrogen-bonded nucleic acid base pairs are intrinsically nonplanar, mainly due to the partial sp³ hybridization of nitrogen atoms of their amino groups and secondary electrostatic interactions. This finding extends the variability of intermolecular interactions of DNA bases in that i) flexibility of the base pairs is larger than has been assumed before, and ii) attractive proton-proton acceptor interactions oriented out of the base pair plane are allowed. For example, all four G…A mismatch base pairs are propeller twisted, and the energy preferences for the nonplanar structures range from less than 0.1 kcal/mol to 1.8 kcal/mol. We predict that nonplanarity of the amino group of guanine in the G(anti)…A(anti) pair of the ApG step of the d(CCAAGATTGG)₂ crystal structure is an important stabilizing factor that improves the energy of this structure by almost 3 kcal/mol. Currently used empirical potentials are not accurate enough to properly cover the interactions associated with amino-group and base-pair nonplanarity.     

Unnatural imidazopyridopyrimidine:naphthyridine base pairs: selective incorporation and extension reaction by Deep Vent (exo? ) DNA polymerase

In our previous communication we reported the enzymatic recognition of unnatural imidazopyridopyrimidine:naphthyridine (Im:Na) base pairs, i.e. ImO^N:NaN^O and ImN^O:NaO^N, using the Klenow fragment exo⁻ [KF (exo⁻)]. We describe herein the successful results of (i) improved enzymatic recognition for ImN^O:NaO^N base pairs and (ii) further primer extension reactions after the Im:Na base pairs by Deep Vent DNA polymerase exo⁻ [Deep Vent (exo⁻)]. Since KF (exo⁻) did not catalyze primer extension reactions after the Im:Na base pair, we carried out a screening of DNA polymerases to promote the primer extension reaction as well as to improve the selectivity of base pair recognition. As a result, a family B DNA polymerase, especially Deep Vent (exo⁻), seemed most promising for this purpose. In the ImO^N:NaN^O base pair, incorporation of NaN^OTP against ImO^N in the template was preferable to that of the natural dNTPs, while incorporation of dATP as well as dGTP competed with that of ImO^NTP when NaN^O was placed in the template. Thus, the selectivity of base pair recognition by Deep Vent (exo⁻) was less than that by KF (exo⁻) in the case of the ImO^N:NaN^O base pair. On the other hand, incorporation of NaO^NTP against ImN^O in the template and that of ImN^OTP against NaO^N were both quite selective. Thus, the selectivity of base pair recognition was improved by Deep Vent (exo⁻) in the ImN^O:NaO^N base pair. Moreover, this enzyme catalyzed further primer extension reactions after the ImN^O:NaO^N base pair to afford a faithful replicate, which was confirmed by MALDI-TOF mass spectrometry as well as the kinetics data for extension fidelity next to the ImN^O:NaO^N base pair. The results presented in this paper revealed that the ImN^O:NaO^N base pair might be a third base pair beyond the Watson–Crick base pairs.     

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

N¹-meA and N³-meC are cytotoxic DNA base methylation lesions that can accumulate in the genomes of various organisms in the presence of S_N2 type methylating agents. We report here the structural characterization of these base lesions in duplex DNA using a cross-linked protein–DNA crystallization system. The crystal structure of N¹-meA:T pair shows an unambiguous Hoogsteen base pair with a syn conformation adopted by N¹-meA, which exhibits significant changes in the opening, roll and twist angles as compared to the normal A:T base pair. Unlike N¹-meA, N³-meC does not establish any interaction with the opposite G, but remains partially intrahelical. Also, structurally characterized is the N⁶-meA base modification that forms a normal base pair with the opposite T in duplex DNA. Structural characterization of these base methylation modifications provides molecular level information on how they affect the overall structure of duplex DNA. In addition, the base pairs containing N¹-meA or N³-meC do not share any specific characteristic properties except that both lesions create thermodynamically unstable regions in a duplex DNA, a property that may be explored by the repair proteins to locate these lesions.     

Poly(amino2 dA-dT) Isomerizes into the Unusual X-DNA Double Helix at Physiological Conditions Inducing Z-DNA in Poly(dG-methyl5dC)

Abstract

It is demonstrated that a two-state conformational isomerization is induced in the poly(amino²-dA-dT) duplex by submillimolar concentrations of divalent magnesium cations in low-salt aqueous solution. The isomerization is fast and has a low degree of cooperativity. The resulting conformer is the unusual X-DNA double helix originally observed with poly(dA-dT) at very high concentrations of CsF. Interestingly, the X form is induced in poly(amino² dA-dT) under the physiological conditions when poly(dG-methyl⁵dC) assumes Z-DNA. The same conditions of stabilization are presumably connected with the fact, observed in previous phosphorus NMR studies, that Z- and X-DNA have similar polydinucleotide backbone architectures. Results presented in this work permit to specify base pair exocyclic groups responsible for the radically different conformational variability of the synthetic DNA molecules containing alternating purine-pyrimidine sequences of GC or AT base pairs.     

Pyrazolo[3,4-d]pyrimidine Nucleic Acids: Adjustment of the dA-dT to the dG-dC Base Pair Stability

Abstract

The pyrazolo[3,4-d]pyrimidine-4,6-diamine nucleosides 2b-d stabilize the dA-dT base pair significantly when the dA-residue is replaced. Oligonucleotide duplexes incorporating 2b-d show a 4–6°C T _m increase per modification. The 7-bromo compound 2b harmonizes the stability of the dA-dT vs. the dG-dC pair. According to this the stability of such duplexes depends no longer on the base pair composition of a DNA molecule.     

Hybridization Properties of the 5-Methyl-isocytidine/isoguanosine Base Pair in Synthetic Oligodeoxynucleotides

Abstract

The hybridization properties of the 5-methyl-isocytidine/isoguanosine base pair in synthetic oligodeoxynucleotides have been investigated. The 5-methyl-isocytidine/isoguanosine base pair has been determined to be isoenergetic with the cytidine/guanosine, and each base can effectively discriminate mismatches.     

Studies on the Effect of Thymine-Mercury-Thymine Stem as a Structural or Functional Motif in DNAzymes

T-Hg-T base pair formation has been demonstrated to be compatible with duplex DNA context, with considerable thermal stability contribution. Here, the T-Hg-T stem in two small DNAzymes 8–17 and 10–23 was studied for its structural and functional roles. The recognition arm 5′ to the cleavage site of 10–23 DNAzyme complex and the stem in the catalytic loop of 8–17 DNAzyme could be replaced by consecutive T-Hg-T stem of different length. The linear relationship between the activity of the complex 10–23DZ-6T+D19–6T and the concentration of Hg²⁺ demonstrated that the T-Hg-T stem contributes thermal stability of the recognition arm binding. The effect of T-Hg-T stem in the catalytic core of 8–17 DNAzyme and the position-dependent effect in 10–23 DNAzyme demonstrated that T-Hg-T base pair is not compatible with canonical base pairs in playing the functions of nucleic acids.     

Solution Structure of a GAAG Tetraloop in Helix 6 of SRP RNA from Pyrococcus furiosus

The NMR structure of a 12-mer RNA derived from the helix 6 of SRP RNA from Pyrococcus furiosus, whose loop-closing base pair is U:G, was determined, and the structural and thermodynamic properties of the RNA were compared with those of a mutant RNA with the C:G closing base pair. Although the structures of the two RNAs are similar to each other and adopt the GNRR motif, the conformational stabilities are significantly different to each other. It was suggested that weaker stacking interaction of the GAAG loop with the U:G closing base pair in 12-mer RNA causes the lower conformational stability.     

Monte Carlo Simulation of Hydration of the Nucleic Acid Fragments

Abstract

Systems containing a base or a base pair and 25 water molecules, as well as a helical stack and 30 water molecules per base pair, have been simulated. Changes in the base hydration shell structure, after the bases have been included into the pair and then into the base pair stack are discussed. Hydration shells of several configurations of the base pair stacks are discussed. Probabilities of formation of the hydrogen-bonded bridges of 1, 2 and 3 water molecules between hydrophilic centres have been estimated. The hydration shell structure was shown to depend on the nature of the base pair and on the stack configuration, while dependence of the global hydration shell characteristics on the stack configuration has been proved to be rather slight. The most typical structural elements of hydration shells, in the glycosidic (minor in B-like conformation) and non-glycosidic (major) grooves, for different configurations of AU and GC stacks, have been found and discussed. The number of hydrogen bonds between water molecules and bases per water molecule was shown to change upon transformation of the stack from A to B configuration. This result is discussed in connection with the reasons for B to A conformational transition and the concept of “water economy”. Hydration shell patterns of NH₂-groups of AU and GC helical stacks differ significantly.     

Synthesis and Triplex Binding Properties of Oligonucleotides Containing a Novel Nucleobase

Abstract

The thiazolo-indole compound 1 bearing the complementary donor-acceptor-donor sites (dad) was designed for specific recognition of an AT inverted base pair in pyrimidine triple helix motif. It was successfully incorporated into 14-mer oligonucleotide using a serinol unit as sugar derivative. The triple helix hybridization studies were examined by means of thermal denaturation experiments with a 26-mer DNA duplex containing the AT inverted base pair.     

15N-Labeled Oligodeoxynucleotides -Useful Probes for 1H-NMR Investigations

Abstract

The amino protons of ¹⁵N-labeled deoxyoligonucleotides were studied as possible structural probes for NMR investigations of the interaction between DNA and regulatory proteins. To apply this strategy, 6-¹⁵NH₂-2′ -deoxyadenoslne, 4-¹⁵NH -2′-deoxycytidine and 2-¹⁵NH -2′-deoxyguanosine were chemically synthesized. The labeled nucleosides were introduced into distinct positions of oligodeoxy-nucleotides by large-scale DNA synthesis. The behaviour of the ¹⁵N-coupled cytidine amino protons in a 18 base pair (bp) lac operator sequence were investigated using H-¹⁵N INDOR spectroscopy .