Monitoring the site-specific incorporation of dual fluorophore-quencher base analogues for target DNA detection by an unnatural base pair system

We developed intramolecular dual fluorophore-quencher base analogues for site-specific incorporation into DNA by an unnatural base pair replication system. An unnatural base pair between 7-(2-thienyl)-imidazo[4,5-b]pyridine (Ds) and 2-nitro-4-propynylpyrrole (Px) exhibits high fidelity in PCR amplification, and the 2-nitropyrrole moiety of Px acts as a quencher. Deoxyribonucleoside triphosphates of Px linked with a fluorophore (Cy3, Cy5 or FAM) were chemically synthesized, and the fluorescent properties and the enzymatic incorporation of the fluorophore-linked dPxTPs into DNA were examined in PCR amplification. The fluorophore-linked dPxTPs were site-specifically incorporated by PCR into DNA, opposite Ds in templates, with high selectivity. Furthermore, we found that the fluorescence of the triphosphates was partially quenched, but increased upon their incorporation into DNA. These dual fluorophore-quencher base analogues would be useful for site-specific DNA labeling and for monitoring the amplification products of target nucleic acid molecules with a specific sequence. We have demonstrated the utility of the fluorophore-linked Px substrates and the Ds-Px pairing in real-time quantitative PCR for target DNA molecule detection.     

An efficient unnatural base pair for PCR amplification

Expansion of the genetic alphabet by an unnatural base pair system provides a powerful tool for modern biotechnology. As an alternative to previous unnatural base pairs, we have developed a new pair between 7-(2-thienyl)imidazo[4,5-b]pyridine (Ds) and 2-nitropyrrole (Pn), which functions in DNA amplification. Pn more selectively pairs with Ds in replication than another previously reported pairing partner, pyrrole-2-carbaldehyde (Pa). The nitro group of Pn efficiently prevented the mispairing with A. High efficiency and selectivity of the Ds-Pn pair in PCR amplification were achieved by using a substrate mixture of the gamma-amidotriphosphate of Ds and the usual triphosphates of Pn and the natural bases, with Vent DNA polymerase as a 3' to 5' exonuclease-proficient polymerase. After 20 cycles of PCR, the total mutation rate of the Ds-Pn site in an amplified DNA fragment was approximately 1%. PCR amplification of DNA fragments containing the unnatural Ds-Pn pair would be useful for expanded genetic systems in DNA-based biotechnology.     

Optimization of unnatural base pair packing for polymerase recognition

As part of an effort to expand the genetic alphabet, we have been examining the ability of predominately hydrophobic nucleobase analogues to pair in duplex DNA and during polymerase-mediated replication. We previously reported the synthesis and thermal stability of unnatural base pairs formed between nucleotides bearing simple methyl-substituted phenyl ring nucleobase analogues. Several of these pairs are virtually as stable and selective as natural base pairs in the same sequence context. Here, we report the characterization of polymerase-mediated replication of the same unnatural base pairs. We find that every facet of replication, including correct and incorrect base pair synthesis, as well as continued primer extension beyond the unnatural base pair, is sensitive to the specific methyl substitution pattern of the nucleobase analogue. The results demonstrate that neither hydrogen bonding nor large aromatic surface area is required for polymerase recognition, and that interstrand interactions between small aromatic rings may be optimized for replication. Combined with our previous results, these studies suggest that appropriately derivatized phenyl nucleobase analogues represent a promising approach toward developing a third base pair and expanding the genetic alphabet.     

Discovery, characterization, and optimization of an unnatural base pair for expansion of the genetic alphabet

DNA is inherently limited by its four natural nucleotides. Efforts to expand the genetic alphabet, by addition of an unnatural base pair, promise to expand the biotechnological applications available for DNA as well as to be an essential first step toward expansion of the genetic code. We have conducted two independent screens of hydrophobic unnatural nucleotides to identify novel candidate base pairs that are well recognized by a natural DNA polymerase. From a pool of 3600 candidate base pairs, both screens identified the same base pair, dSICS:dMMO2, which we report here. Using a series of related analogues, we performed a detailed structure-activity relationship analysis, which allowed us to identify the essential functional groups on each nucleobase. From the results of these studies, we designed an optimized base pair, d5SICS:dMMO2, which is efficiently and selectively synthesized by Kf within the context of natural DNA.     

A new unnatural base pair system between fluorophore and quencher base analogues for nucleic acid-based imaging technology

In the development of orthogonal extra base pairs for expanding the genetic alphabet, we created novel, unnatural base pairs between fluorophore and quencher nucleobase analogues. We found that the nucleobase analogue, 2-nitropyrrole (denoted by Pn), and its 4-substitutions, such as 2-nitro-4-propynylpyrrole (Px) and 4-[3-(6-aminohexanamido)-1-propynyl]-2-nitropyrrole (NH(2)-hx-Px), act as fluorescence quenchers. The Pn and Px bases specifically pair with their pairing partner, 7-(2,2'-bithien-5-yl)imidazo[4,5-b]pyridine (Dss), which is strongly fluorescent. Thus, these unnatural Dss-Pn and Dss-Px base pairs function as reporter-quencher base pairs, and are complementarily incorporated into DNA by polymerase reactions as a third base pair in combination with the natural A-T and G-C pairs. Due to the static contact quenching, the Pn and Px quencher bases significantly decreased the fluorescence intensity of Dss by the unnatural base pairings in DNA duplexes. In addition, the Dss-Px pair exhibited high efficiency and selectivity in PCR amplification. Thus, this new unnatural base pair system would be suitable for detection methods of target nucleic acid sequences, and here we demonstrated the applications of the Dss-Pn and Dss-Px pairs as molecular beacons and in real-time PCR. The genetic alphabet expansion system with the replicable, unnatural fluorophore-quencher base pair will be a useful tool for sensing and diagnostic applications, as well as an imaging tool for basic research.     

Ultrafast deactivation of an excited cytosine-guanine base pair in DNA

Multiconfigurational ab initio calculations and QM/MM molecular dynamics simulations of a photoexcited cytosine-guanine base pair in both gas phase and embedded in the DNA provide detailed structural and dynamical insights into the ultrafast radiationless deactivation mechanism. Photon absorption promotes transfer of a proton from the guanine to the cytosine. This proton transfer is followed by an efficient radiationless decay of the excited state via an extended conical intersection seam. The optimization of the conical intersection revealed that it has an unusual topology, in that there is only one degeneracy-lifting coordinate. This is the central mechanistic feature for the decay both in vacuo and in the DNA. Radiationless decay occurs along an extended hyperline nearly parallel to the proton-transfer coordinate, indicating the proton transfer itself is not directly responsible for the deactivation. The seam is displaced from the minimum energy proton-transfer path along a skeletal deformation of the bases. Decay can thus occur anywhere along the single proton-transfer coordinate, accounting for the remarkably short excited-state lifetime of the Watson-Crick base pair. In vacuo, decay occurs after a complete proton transfer, whereas in DNA, decay can also occur much earlier. The origin of this effect lies in the temporal electrostatic stabilization of dipole in the charge-transfer state in DNA.     

Synthesis of C-nucleosides designed to participate in triplex formation with native DNA: specific recognition of an A:T base pair in DNA

[structure: see text] We have previously described a system of 2-aminoquinoline- and 2-aminoquinazoline-based C-deoxynucleosides (TRIPsides) that are designed to be incorporated into oligomers that can specifically bind in the major groove via Hoogsteen base pairing to any sequence of native DNA. The four TRIPsides are termed antiGC, antiCG, antiTA, and antiAT with respect to the Watson-Crick base pair targets that they bind. The first three TRIPsides have been prepared, characterized, and shown to form stable and sequence-specific triplexes. In the present study, we describe the preparation of two molecules, 2-amino-4-(2'-deoxy-beta-D-ribofuranosyl)quinazoline (7) and 2-amino-6-fluoro-4-(2'-deoxy-beta-D-ribofuranosyl)quinoline (14), that can serve as the remaining antiAT TRIPside. The phosphoramidites of 7 and 14 were prepared, but only the latter was successfully incorporated into DNA oligomers. It is demonstrated using UV-visible melting experiments that 14 forms sequence-specific intramolecular triplets with A:T base pairs at physiological pH.     

Tautomerism and isomerism of guanine–cytosine DNA base pair: Ab initio and density functional theory approaches

The relative stabilities of guanine–cytosine (G–C) DNA base pairs are theoretically investigated with a focus on the keto–enol tautomerism as well as on the cis–trans enol isomerism by using both ab initio method and the density functional theory. The G–C pairs of the keto tautomers turn out to be in general more stable than those of the enol tautomers, 9H-guanine pair, 9KK (see the notation below), being the most stable one. The stability of the G–C pairs appears to be affected by various factors including the keto–enol tautomerization, cis–trans enol isomerization, and the steric hindrance between two tautomeric pairs. Although the B3LYP calculations tend to underestimate the binding energies, in addition, it is shown that the binding energy of G–C pairs interacting through hydrogen bonds can be reasonably calculated with the DFT method, contrary to the base pairs with stacked configurations.     

A density functional theory study for the hydrogen-bonded nucleic acid base pair: cytosine dimer

Theoretical investigation for the geometric and energetic properties, rotational constants, harmonic vibrational frequencies, and binding energies of nucleic acid base pair, cytosine dimer, are carried out by using the density functional theory method. The dimer structures resulting from both the keto and the enol (cis/trans) tautomers are investigated in the present study. Various isomers are considered to find the stable structures of the cytosine dimer. The planar cytosine dimer, K-K3 with C2h symmetry, resulting from nonplanar keto tautomers, is found to be thermodynamically most stable out of the four different stable isomers and having the highest binding energy value, 19.51 kcal/mol (including basis set superposition error correction). The vibrational frequency analysis also suggests a red shift of 367.97 cm(-1) for the hydrogen-bonding K-K3 symmetric dimer with two hydrogen bond lengths, each of length 1.913 angstroms. Moreover, charge distribution (ChelpG charges), Laplacian electronic density distribution, and the dimerization equilibrium for the most stable dimer, K-K3, have also been investigated using the same method and the basis set.     

Structure of a copper-mediated base pair in DNA.

Stable and selective DNA base pairing by metal coordination was recently demonstrated with nucleotides containing complementary pyridine-2,6-dicarboxylate (Dipic) and pyridine (Py) bases (Meggers, E.; Holland, P. L.; Tolman; W. B.; Romesberg, F. E.; Schultz, P. G. J. Am. Chem. Soc. 2000, 122, 10714-10715). To understand the structural consequences of introducing this novel base pair into DNA we have solved the crystal structure of a duplex containing the metallo-base pair. The structure shows that the bases pair as designed, but in a Z-DNA conformation. The structure also provides a structural explanation for the B- to Z-DNA transition in this duplex. Further solution studies demonstrate that the metallo-base pair is compatible with Z- or B-DNA conformations, depending on the duplex sequence.     

Quantum chemical characterization of the cytosine: 2‐Aminopurine base pair

The nature of the base pairing between cytosine and 2‐aminopurine is investigated by means of quantum mechanical calculations including electron correlation and accounting for the effects of aqueous solvation. At neutral pH, both a neutral wobble base pair and a Watson–Crick‐like base pair having a protonated 2‐aminopurine are predicted to be close to one another in energy; other previously proposed forms are found to be too high in energy to be of significant chemical interest. Accounting for the energetics of helix embedding suggests that the equilibrium between the two low‐energy motifs is quite sensitive to local environment. © 2001 John Wiley & Sons, Inc. J Comput Chem 22: 1167–1179, 2001     

The elusive atomic rationale for DNA base pair stability

A systematic analysis of the electrostatic interaction between 27 natural DNA base pairs was carried out, based on ab initio correlated wave functions and the topology of the electron density. Using high rank multipole moments we show that the atomic partitioning of the interaction energy contains many substantial contributions between distant atoms. Profiles of cumulative energy versus internuclear distance show large fluctuations and provide an electrostatic fingerprint of the partitioning of interaction energy in a complex. A quantified comparison between each pair of energy profiles, one for each base pair, makes clear that there is no correlation between the total base pair interaction energy and the shape of the profile. In other words, base pairs with similar interaction energy are not stable for the same reasons in terms of atomic partitioning. In summary, simple rules to rationalize the pattern of energetic stability of naturally occurring base pairs in terms of subsets of atoms are elusive. Our work cautions against inappropriate use of Jorgensen's secondary interaction hypothesis.     

Efficient incorporation of a copper hydroxypyridone base pair in DNA

Recently, we reported the first artificial nucleoside for alternative DNA base pairing through metal complexation (J. Org. Chem. 1999, 64, 5002-5003). In this regard, we report here the synthesis of a hydroxypyridone-bearing nucleoside and the incorporation of a neutral Cu(2+)-mediated base pair of hydroxypyridone nucleobases (H-Cu-H) in a DNA duplex. When the hydroxypyridone bases are incorporated into the middle of a 15 nucleotide duplex, the duplex displays high thermal stabilization in the presence of equimolar Cu(2+) ions in comparison with a duplex containing an A-T pair in place of the H-H pair. Monitoring temperature dependence of UV-absorption changes verified that a Cu(2+)-mediated base pair is stoichiometrically formed inside the duplex and dissociates upon thermal denaturation at elevated temperature. In addition, EPR and CD studies suggested that the radical site of a Cu(2+) center is formed within the right-handed double-strand structure of the oligonucleotide. The present strategy could be developed for controlled and periodic spacing of neutral metallobase pairs along the helix axis of DNA.     

Drug-induced stabilisation of a mismatched C-T base pair in a DNA hairpin

We have shown that a key feature of drug binding, namely specific G-C base pair recognition at a 5'-TG step, can induce a number of novel structural features when an extrahelical base is inserted in close proximity to the drug binding site; we have clearly demonstrated the formation of a stabilised C-T mismatched base pair at a non-terminal site.