Specific Purine‐Purine Base Pairing in Linear Alanyl‐Peptide Nucleic Acids

Purine‐purine base pairing with guanine, isoguanine, 2,6‐diaminopurine, and xanthine is investigated within the topology of alanyl‐PNA. Alanyl‐PNA is based on a regular peptide backbone with alternating configuration of the amino acids. The nucleobases are covalently linked as side chains. Their distance in peptides with β‐sheet conformation is similar to the favored base‐pair stacking distance. Therefore, alanyl‐PNA provides self‐pairing linear double‐strands. The linear double‐strand topology does not restrict base‐pair size and geometry. The favored base pairs are formed mostly dependent on recognition by H‐bonding. The synthesis of the nucleo‐amino acids with unnatural nucleobases and their oligomerization is described. Hexamers and a tetramer based on 2,6‐diaminopurine‐xanthine and guanine‐isoguanine base pairs were observed with very high stabilities. For xanthine‐xanthine self‐pairing, an unusual tridentate reverse Watson‐Crick pairing mode is indicated, that is only possible with xanthines pairing in different tautomeric forms. To investigate the nature of xanthine‐xanthine base pairs in more detail, quantum‐chemical calculations were performed. They establish the easier tautomerization of xanthine compared to uracil and indicate that, in the AO basis‐set limit, the tridentate pairing mode with mixed tautomers is favored.     

5-Aza-7-deazaguanine–Isoguanine and Guanine–Isoguanine Base Pairs in Watson–Crick DNA: The Impact of Purine Tracts,Clickable Dendritic Side Chains,and Pyrene Adducts

The Watson–Crick coding system depends on the molecular recognition of complementary purine and pyrimidine bases. Now, the construction of hybrid DNAs with Watson–Crick and purine–purine base pairs decorated with dendritic side chains was performed. Oligonucleotides with single and multiple incorporations of 5-aza-7-deaza-2′-deoxyguanosine, its tripropargylamine derivative, and 2′-deoxyisoguanosine were synthesized. Duplex stability decreased if single modified purine–purine base pairs were inserted, but increased if pyrene residues were introduced by click chemistry. A growing number of consecutive 5-aza-7-deazaguanine–isoguanine base pairs led to strong stepwise duplex stabilization, a phenomenon not observed for the guanine–isoguanine base pair. Spacious residues are well accommodated in the large groove of purine–purine DNA tracts. Changes to the global helical structure monitored by circular dichroism spectroscopy show the impact of functionalization to the global double-helix structure. This study explores new areas of molecular recognition realized by purine base pairs that are complementary in hydrogen bonding, but not in size, relative to canonical pairs.     

Rational design of hetero-ring-expanded guanine analogs with enhanced properties for modified DNA building blocks

The properties and modes of recognition of physiological DNAs associated with the four natural nucleobases might be extended, in principle, by the design of non-natural nucleobase derivatives. The goal is an expansion of the genetic alphabet, with the possible outcome of producing new DNAs with improved physical or biological properties. In this work, a new series of hetero-ring-expanded guanine analogs are proposed, and their relevant structural characteristics and electronic properties are determined by density functional theory. The stabilities of the decamer DNA duplexes (dn.dC)10 (where n represents the corresponding expanded guanine analog designed here) are also examined, using molecular dynamics. The simulations show that the designed motifs can form stable DNA-like structures. We determined the pairing energies for the Watson-Crick (WC) hydrogen-bonded dimers between the expanded G-analogs and the natural C, and found that the pairing energies are close to those of the natural GC pair. The calculated adiabatic ionization potentials (IPs) of the size-expanded guanine analogs and their base pairs, and the corresponding vertical ionization potentials, show that some are distinctly smaller than the corresponding natural versions. The HOMO-LUMO energy gaps for most of the size-expanded guanine analogs and their WC base pairs are considerably lower than those of the corresponding natural base and base pairs. Thus, the expanded G bases may be considered as DNA genetic motifs, and they may serve as building blocks for potential biological applications and the development of molecular electronic devices.     

A post‐SCF quantum chemistry study on local minima of 8‐oxo‐guanine stacked with all four nucleic acid bases in B‐DNA conformations

The post SCF MP2/6‐31G*(d=0.25) method was applied to obtain potential energy surface of 8‐oxoguanine stacked with all four canonical DNA bases. The spatial neighbourhood was scanned of stacked complexes found in the native B‐DNA. The presented results suggest that the hydroxyl radical modification of guanine at C₈ position has significant impact on structural, energetic, orbital and electrostatic properties of stacked complexes with canonical DNA bases. The pair stabilization energy, including electron correlation terms, suggests that the 5′‐A/GA‐3′ pair is the most stable among all of the studied complexes. The 8‐oxo‐guanine has been found as a source of significant changes in electroaccepting properties compared to stacked pairs formed by canonical guanine since both electron affinities and localization of HOMO orbital were altered. However, electro‐donation abilities are not modified after replacement of guanine with 8‐oxo‐guanine irrespectively on the context of B‐DNA bases.     

Imidazolo‐dC Metal‐Mediated Base Pairs: Purine Nucleosides Capture Two Ag+ Ions and Form a Duplex with the Stability of a Covalent DNA Cross‐Link

8‐Phenylimidazolo‐dC (^phImidC, 2 ) forms metal‐mediated DNA base pairs by entrapping two silver ions. To this end, the fluorescent “purine” 2′‐deoxyribonucleoside 2 has been synthesised and converted into the phosphoramidite 6 . Owing to the ease of nucleobase deprotonation, the new Ag⁺‐mediated base pair containing a “purine” skeleton is much stronger than that derived from the pyrrolo‐ [3,4‐d]pyrimidine system (^phPyrdC, 1 ). The silver‐mediated ^phImidC–^phImidC base pair fits well into the DNA double helix and has the stability of a covalent cross‐link. The formation of such artificial metal base pairs might not be limited to DNA but may be applicable to other nucleic acids such as RNA, PNA and GNA as well as other biopolymers.     

Contiguous metal-mediated base pairs comprising two Ag(I) ions

The incorporation of transition‐metal ions into nucleic acids by using metal‐mediated base pairs has proved to be a promising strategy for the site‐specific functionalization of these biomolecules. We report herein the formation of Ag⁺‐mediated Hoogsteen‐type base pairs comprising 1,3‐dideaza‐2′‐deoxyadenosine and thymidine. By defunctionalizing the Watson–Crick edge of adenine, the formation of regular base pairs is prohibited. The additional substitution of the N3 nitrogen atom of adenine by a methine moiety increases the basicity of the exocyclic amino group. Hence, 1,3‐dideazaadenine and thymine are able to incorporate two Ag⁺ ions into their Hoogsteen‐type base pair (as compared with one Ag⁺ ion in base pairs with 1‐deazaadenine and thymine). We show by using a combination of experimental techniques (UV and circular dichroism (CD) spectroscopies, dynamic light scattering, and mass spectrometry) that this type of base pair is compatible with different sequence contexts and can be used contiguously in DNA double helices. The most stable duplexes were observed when using a sequence containing alternating purine and pyrimidine nucleosides. Dispersion‐corrected density functional theory calculations have been performed to provide insight into the structure, formation and stabilization of the twofold metalated base pair. They revealed that the metal ions within a base pair are separated by an Ag???Ag distance of about 2.88 Å. The Ag–Ag interaction contributes some 16 kcal mol^?1 to the overall stability of the doubly metal‐mediated base pair, with the dominant contribution to the Ag–Ag bonding resulting from a donor–acceptor interaction between silver 4d‐type and 4s orbitals. These Hoogsteen‐type base pairs enable a higher functionalization of nucleic acids with metal ions than previously reported metal‐mediated base pairs, thereby increasing the potential of DNA‐based nanotechnology.     

Nanoswitches based on DNA base pairs: why adenine-thymine is less suitable than guanine-cytosine.

Substituted Watson–Crick guanine–cytosine (GC) base pairs were recently shown to yield robust three‐state nanoswitches. Here, we address the question: Can such supramolecular switches also be based on Watson–Crick adenine‐thymine (AT) base pairs? We have theoretically analyzed AT pairs in which purine‐C8 and/or pyrimidine‐C6 positions carry a substituent X=NH^?, NH₂, NH₃⁺ (N series), O^?, OH or OH₂⁺ (O series), using the generalized gradient approximation (GGA) of density functional theory at the BP86/TZ2P level. Thus, we explore the trend in geometrical shape and hydrogen bond strengths in AT pairs along a series of stepwise protonations of the substituents. Introducing a charge on the substituents leads to substantial and characteristic changes in the individual hydrogen bond lengths when compared to the neutral AT pair. However, the trends along the series of negative, neutral, and positive substituents are less systematic and less pronounced than for GC. In certain instances, internal proton transfer from thymine to adenine occurs. Our results suggest that AT is a less suitable candidate than GC in the quest for chemically controlled nanoswitches.     

Calculation of the stabilization energies of oxidatively damaged guanine base pairs with guanine

DNA is constantly exposed to endogenous and exogenous oxidative stresses. Damaged DNA can cause mutations, which may increase the risk of developing cancer and other diseases. G:C-C:G transversions are caused by various oxidative stresses. 2,2,4-Triamino-5(2H)-oxazolone (Oz), guanidinohydantoin (Gh)/iminoallantoin (Ia) and spiro-imino-dihydantoin (Sp) are known products of oxidative guanine damage. These damaged bases can base pair with guanine and cause G:C-C:G transversions. In this study, the stabilization energies of these bases paired with guanine were calculated in vacuo and in water. The calculated stabilization energies of the Ia:G base pairs were similar to that of the native C:G base pair, and both bases pairs have three hydrogen bonds. By contrast, the calculated stabilization energies of Gh:G, which form two hydrogen bonds, were lower than the Ia:G base pairs, suggesting that the stabilization energy depends on the number of hydrogen bonds. In addition, the Sp:G base pairs were less stable than the Ia:G base pairs. Furthermore, calculations showed that the Oz:G base pairs were less stable than the Ia:G, Gh:G and Sp:G base pairs, even though experimental results showed that incorporation of guanine opposite Oz is more efficient than that opposite Gh/Ia and Sp.     

Interaction of angelicin with DNA‐bases (III) DFT and ab initio second‐order Moeller–Plesset study

Angelicin geometry was optimized at MP2/6‐31+G(d,p) level and compared with X‐ray experimental data. The highest π‐electron density was found to be localized on C1? C2 and on C13? C14 as confirmed by the calculated bond length and bond order values. Spectrophptometric properties of angelicin were measured and compared with the computed within the TD‐DFT. Quantum chemical methods were used to study the interaction of angelicin, as a nonlinear furocoumarin, with DNA bases and base pairs. The interactions with DNA bases and base pairs were studied to shade more light on the nature of the intercalation binding forces between angelicin and DNA. Comparing computed electronic properties of angelicin with that of linear psoralens show that the former is a weaker intercalator. The geometry of complexes of angelicin with adenine, thymine, adenine–thymine base pair, cytocine, guanine as well as cytocine–guanine base pair have been optimized in two main orientations, planar and stacked, at the levels of B3LYP/cc‐pVDZ, MP2/6‐31G(d,p) and MP2/cc‐pVDZ. Effect of vertical distance and rotational angle between the stacked molecules on the interaction energy were investigated by the aforementioned methods in gas phase and water media. It was found that ab initio methods which account for the electron correlation effects are the minimum level for studying the noncovalent interactions. © 2009 Wiley Periodicals, Inc. Int J Quantum Chem, 2010     

Acceleration of Long‐Range Photoinduced Electron Transfer through DNA by Hydroxyquinolines as Artificial Base Pairs

The C‐nucleoside based on the hydroxyquinoline ligand (Hq) is complementary to itself and forms stable Hq–Hq pairs in double‐stranded DNA. These artificial Hq–Hq pairs may serve as artificial electron carriers for long‐range photoinduced electron transfer in DNA, as elucidated by a combination of gel electrophoretic analysis of irradiated samples and time‐resolved transient absorption spectroscopy. For this study, the Hq–Hq pair was combined with a DNA‐based donor–acceptor system consisting of 6‐N,N‐dimethylaminopyrene conjugated to 2′‐deoxyuridine as photoinducible electron donor, and methyl viologen attached to the 2′‐position of uridine as electron acceptor. The Hq radical anion was identified in the time‐resolved measurements and strand cleavage products support its role as an intermediate charge carrier. Hence, the Hq–Hq pair significantly enhances the electron hopping capability of DNA compared to natural DNA bases over long distances while keeping the self‐assembly properties as the most attractive feature of DNA as a supramolecular architecture.     

Hydrophobic, Non-Hydrogen-Bonding Bases and Base Pairs in DNA

We report the properties of hydrophobic isosteres of pyrimidines and purines in synthetic DNA duplexes. Phenyl nucleosides 1 and 2 are nonpolar isosteres of the natural thymidine nucleoside, and indole nucleoside 3 is an analog of the complementary purine 2-aminodeoxyadenosine. The nucleosides were incorporated into synthetic oligodeoxynucleotides and were paired against each other and against the natural bases. Thermal denaturation experiments were used to measure the stabilities of the duplexes at neutral pH. It is found that the hydrophobic base analogs are nonselective in pairing with the four natural bases but selective for pairing with each other rather than with the natural bases. For example, compound 2 selectively pairs with itself rather than with A, T, G, or C; the magnitude of this selectivity is found to be 6.5-9.3 °C in Tm or 1.5-1.8 kcal/mol in free energy (25 °C). All possible hydrophobic pairing combinations of 1, 2, and 3 were examined. Results show that the pairing affinity depends on the nature of the pairs and on position in the duplex. The highest affinity pairs are found to be the 1-1 and 2-2 self-pairs and the 1-2 heteropair. The best stabilization occurs when the pairs are placed at the ends of duplexes rather than internally; the internal pairs may be destabilized by imperfect steric mimicry which leads to non-ideal duplex structure. In some cases the hydrophobic pairs are significantly stabilizing to the DNA duplex; for example, when situated at the end of a duplex, the 1-1 pair is more stabilizing than a T-A pair. When situated internally, the affinity of the 1-1 pair is the same as, or slightly better than, the analogous T-T mismatch pair, which is known to have two hydrogen bonds. The studies raise the possibility that hydrogen bonds may not always be required for the formation of stable duplex DNA-like structure. In addition, the results point out the importance of solvation and desolvation in natural base pairing, and lend new support to the idea that hydrogen bonds in DNA may be more important for specificity of pairing than for affinity. Finally, the study raises the possibility of using these or related base pairs to expand the genetic code beyond the natural A-T and G-C pairs.     

Hetero‐Selective DNA‐Like Duplex Stabilized by Donor–Acceptor Interactions

We report on the characterization of a novel hetero‐selective DNA‐like duplex of pyrene and anthraquinone pseudo base pairs. The pyrene/anthraquinone pairs showed excellent selectivity in hetero‐recognition and even trimers were found to form a hetero‐duplex. Pyrene and anthraquinone moieties were tethered on acyclic D ‐threoninol linkers and linked to adjacent residues by using standard phosphoramidite chemistry. When pyrene and anthraquinone were incorporated at pairing positions in complementary strands of natural DNA oligonucleotides, the duplex was stabilized significantly. Moreover, a pyrene hexamer and an anthraquinone hexamer formed a stable artificial hetero‐duplex without the assistance of natural base pairs. The pyrene/anthraquinone pair was so stable that even trimers formed a hetero‐duplex under conditions in which natural DNA strands of three residues do not.     

Ab initio quantum chemistry studies on the coding properties of cytosine derivatives generated by hydroxyl radical in aerobic conditions

The coding properties of four free radicals derived cytosine modifications were characterised by ab initio quantum chemistry method. The dimers geometry was optimised without any restrictions. The analysis was focused on the pairs consisting of a standard DNA base and one of the following cytosine derivatives: 5,6-dihydroxycytosine (1); 5,6-dihydroxyuracil (2); uracil glycol (3); and isodialuric acid (4). The presented data allow to conclude that all studied derivatives are able to form the most stable pairs with guanine. However, other pairs are also possible. In non-polar conditions the 5,6-dihydroxycytosine (1) pair with cytosine in addition to a normal pairing with guanine. This may stand for CG transversion. The significant impact of the environment polarity on the dimers stabilisation energy was observed. The potential mispairing is enriched in the polar conditions The 5,6-dihydroxyuracil (2) and isodialuric acid (4) may form stable pairs also with adenine. This may lead to CT transition. The mispairing of uracil glycol (3) was found as insignificant.     

5‐Mercuricytosine: An Organometallic Janus Nucleobase

The base‐pairing properties of 5‐mercuricytosine have been explored at the monomer level by NMR titrations and at the oligonucleotide level by melting temperature measurements. The NMR studies revealed a relatively high affinity for guanine, hypoxanthine, and uridine, that is, bases that are deprotonated upon coordination of Hg^II. Within an oligonucleotide duplex, 5‐mercuricytosine formed Hg^II‐mediated base pairs with thymine and guanine. In the former case, the duplex formed was as stable as the respective duplex comprising solely Watson–Crick base pairs. Based on detailed thermodynamic analysis of the melting curves, the stabilization by the Hg^II‐mediated base pairs may be attributed to a comparatively low entropic penalty of hybridization.     

Properties of the optimal environment inducing tautomerization of complementary base pairs

The optimal environment charge configurations are predicted for the tautomerization of complementary base pairs into their corresponding rare forms, and vice versa. Results indicate that cations approaching the N₃ guanine site may induce tautomerization of the normal guanine—cytosine (G---C) base pair into its rare form. The reverse process requires that the cation approach the O₂ thymine site of the rare adenine*—thymine* pair (A*---31T*) or the O₆ guanine site of rare guanine*—cytosine* base pair (G*---C*). Possible mutagenic and antimutagenic roles of metal cations approaching base pairs are also discussed.     

Electronic properties of metal-modified DNA base pairs

The electronic properties of several metal-modified Watson-Crick guanine-cytosine base pairs are investigated by means of first-principle density functional theory calculations. Focus is placed on a new structure recently proposed as a plausible model for building an antiparallel duplex with Zn-guanine-cytosine pairs, but we also inspect several other conformations and the incorporation of Ag and Cu ions. We analyze the effects induced by the incorporation of one metal cation per base pair by comparing the structures and the electronic properties of the metalated pairs to those of the natural guanine-cytosine pair, particularly for what concerns the modifications of energy levels and charge density distributions of the frontier orbitals. Our results reveal the establishment of covalent bonding between the metal cation and the nucleobases, identified in the presence of hybrid metal-guanine and metal-cytosine orbitals. Attachment of the cation can occur either at the N1 or the N7 site of guanine and is compatible with altering or not altering the H-bond pattern of the natural pair. Cu(II) strongly contributes to the hybridization of the orbitals around the band gap, whereas Ag(I) and Zn(II) give hybrid states farther from the band gap. Most metalated pairs have smaller band gaps than the natural guanine-cytosine pair. The band gap shrinking along with the metal-base coupling suggests interesting consequences for electron transfer through DNA double helices.     

Microwave assisted synthesis of 2,6‐substituted aromatic‐aminopurine derivatives

A series of novel 2, 6‐diaromatic‐aminopurines (6a–6t) have been synthesized from guanine and characterized fully. The effects of different catalysts on the N‐alkylation of 2‐position of purine ring were discussed. J. Heterocyclic Chem., (2011).     

7‐Iodo‐5‐aza‐7‐deazaguanine ribonucleoside: crystal structure,physical properties,base‐pair stability and functionalization

The positional change of nitrogen‐7 of the RNA constituent guanosine to the bridgehead position‐5 leads to the base‐modified nucleoside 5‐aza‐7‐deazaguanosine. Contrary to guanosine, this molecule cannot form Hoogsteen base pairs and the Watson–Crick proton donor site N3—H becomes a proton‐acceptor site. This causes changes in nucleobase recognition in nucleic acids and has been used to construct stable `all‐purine' DNA and DNA with silver‐mediated base pairs. The present work reports the single‐crystal X‐ray structure of 7‐iodo‐5‐aza‐7‐deazaguanosine, C<sub>10</sub>H<sub>12</sub>IN<sub>5</sub>O<sub>5</sub> ( 1 ). The iodinated nucleoside shows an anti conformation at the glycosylic bond and an N conformation (O4′‐endo) for the ribose moiety, with an antiperiplanar orientation of the 5′‐hydroxy group. Crystal packing is controlled by interactions between nucleobase and sugar moieties. The 7‐iodo substituent forms a contact to oxygen‐2′ of the ribose moiety. Self‐pairing of the nucleobases does not take place. A Hirshfeld surface analysis of 1 highlights the contacts of the nucleobase and sugar moiety (O—H…O and N—H…O). The concept of pK‐value differences to evaluate base‐pair stability was applied to purine–purine base pairing and stable base pairs were predicted for the construction of `all‐purine' RNA. Furthermore, the 7‐iodo substituent of 1 was functionalized with benzofuran to detect motional constraints by fluorescence spectroscopy.     

Bulged Guanine is Uniquely Sensitive to Damage Caused by Visible‐Light Irradiation of Ethidium Bound to DNA: A Possible Role in Mutagenesis

The interaction of ethidium bromide (=3,8‐diamino‐5‐ethyl‐6‐phenylphenanthridinium bromide; EB) with a series of duplex DNA oligomers having single‐base bulges and single‐base mis‐pairs was investigated (Fig. 1). Physical and spectroscopic analysis reveals no definitive evidence for selective binding of EB at the bulge or mis‐pair. However, irradiation of the bound EB with VIS light leads to lesions in the DNA selectively in the sequence having a bulged guanine. This reaction is attributed to the formation of an exciplex between the lowest excited singlet state of the EB and the bulged guanine. The exciplex is trapped by H₂O, which initiates a sequence of reactions that lead to piperidine‐requiring strand cleavage at this site. Significantly, the damaged bulged guanine is not recognized by E. coli formamidopyrimidine glycosylase (Fpg), which is part of a base‐excision repair system for oxidative damage to DNA. Thus, DNA containing a bulged guanine and having a bound intercalator may be irreparably damaged by exposure to VIS light, even though normal duplex DNA is relatively inert under these conditions.     

Voltammetric Determination of Purine Bases Using a Carbon Electrode Modified With Hybrid Silica Film

Hybrid silica films containing cation‐exchange polyelectrolytes were designed and used to modify a glassy carbon electrode (GCE) for voltammetric determination of purine bases. Hybrid silica‐polyelectrolyte films synthesised in the presence of adenine as structure directed component have demonstrated enhanced sorption capacity to purine base. The anodic peaks of adenine and guanine at a hybrid film‐modified GCE were observed at +1.55 and +1.1 V, respectively, in phosphate buffer solution at pH 3.5. Oxidation currents of adenine and guanine were proportional to their concentration in the range of 0.02–0.50 mM, with a detection limit of 0.015 mM. The developed method was used to determine adenine in adenosine triphosphate and purine bases in hydrolyzed solutions of DNA and demonstrated good metrological characteristics.