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.

We prepared reversed dye clusters by hybridizing two RNA oligomers, each of which tethered dyes (Methyl Red, 4′-methylthioazobenzene, and thiazole orange) on D-threoninols (threoninol nucleotides) at the center of their strands. NMR spectroscopic analyses revealed that two dyes from each strand were axially stacked in an antiparallel manner to each other in the duplex, and were located adjacent to the 3′-side of a natural nucleobase. Interestingly, this positional relationship of the dyes was completely the opposite of that assembled in DNA that we reported previously: dyes in DNA were located adjacent to the 5′-side of a natural nucleobase. This observation was also consistent with the circular dichroism of dimerized dyes in which the Cotton effect of the dyes (i.e., the winding properties of two dyes) was inverted in RNA relative to that in DNA. Further spectroscopic analyses revealed that clustering of the dyes on RNA duplexes induced distinct hypsochromicity and narrowing of the band, thus demonstrating that the dyes were axially stacked (i.e., H-aggregates) even on an A-type helix. On the basis of these results, we also prepared heterodimers of a fluorophore (thiazole orange) and quencher (Methyl Red) in an RNA duplex. Fluorescence from thiazole orange was found to be strongly quenched by Methyl Red due to the excitonic interaction, so that the ratio of fluorescent intensities of the RNA–thiazole orange conjugate with and without its complementary strand carrying a quencher became as high as 27. We believe that these RNA–dye conjugates are potentially useful probes for real-time monitoring of RNA interference (RNAi) mechanisms.

Asymmetric dye clusters with a single fluorophore (Cy3) and multiple quenchers (4′-methylthioazobenzene-4-carboxylate, methyl red, and 4′-dimethylamino-2-nitroazobenzene-4-carboxylate) were prepared. The dye and one-to-five quenchers were tethered through D-threoninol to opposite strands of a DNA duplex. NMR analysis revealed that the clusters with a single fluorophore and two quenchers formed a sandwich-like structure (antiparallel H-aggregates). The melting temperatures of all the heteroclusters were almost the same, although structural distortion should become larger, as the number of quenchers increased. An asymmetric heterocluster of a single fluorophore and two quenchers showed larger excitonic interaction (i.e., hypochromicity of Cy3), than did a single Cy3 and a single quencher. Due to the larger exciton coupling between the dyes, the 1:2 heterocluster suppressed the background emission more efficiently than the 1:1 cluster. However, more quenchers did not enhance quenching efficiency due to the saturation of exciton coupling with two quenchers. Finally, this asymmetric 1:2 heterocluster was introduced into the stem region of a molecular beacon (MB; also known as an in-stem MB) targeting the fusion site in the L6 BCR-ABL fusion gene. With this MB design, the signal/background ratio was as high as 68 due to efficient suppression of background emission resulting from the maximized excitonic interaction.

Efficient DNA nick sealing catalyzed by T4 DNA ligase was carried out on a modified DNA template in which an intercalator such as azobenzene had been introduced. The intercalator was attached to a D-threoninol linker inserted into the DNA backbone. Although the structure of the template at the point of ligation was completely different from that of native DNA, two ODNs could be connected with yields higher than 90 % in most cases. A systematic study of sequence dependence demonstrated that the ligation efficiency varied greatly with the base pairs adjacent to the azobenzene moiety. Interestingly, when the introduced azobenzene was photoisomerized to the cis form on subjection to UV light (320–380 nm), the rates of ligation were greatly accelerated for all sequences investigated. These unexpected ligations might provide a new approach for the introduction of functional molecules into long DNA strands in cases in which direct PCR cannot be used because of blockage of DNA synthesis by the introduced functional molecule. The biological significance of this unexpected enzymatic action is also discussed on the basis of kinetic analysis,.

In this study, we propose that three consecutive cationic p-methylstilbazoles tethered on D-threoninols (Z residues) at 5′ termini act as a unique “glue” connecting DNA duplexes by their interstrand cluster formation. Interstrand clustering of p-methylstilbazoles (ZZZ triplets) induces narrowing and hypsochromic shift of bands at 350 nm, which can be assigned to the absorption of p-methylstilbazole. However, single-stranded DNA conjugates involving a ZZZ triplet at the 5′ terminus of 8-mer native nucleotides is found not to induce such large spectral changes, which implies that the intrinsic self-assembling property of ZZZ triplets is weak. Interestingly, when this conjugate is hybridized with a complementary 8-mer native oligonucleotide, a remarkable spectral change is observed, indicating the dimerization of a duplex through the interstrand clustering of ZZZ triplets. Dimerization of the duplex is also evidenced by cold-spray ionization mass spectrometry. This interstrand clustering is observed only when a ZZZ triplet is tethered to a 5′ rather than 3′ terminus. Furthermore, the stability of the interstrand cluster increases by increasing the number of nucleobases of the DNA portion, and when mismatched base pairs are incorporated or when a base next to the Z residue is deleted, the stability substantially drops. When we apply the ZZZ triplet to the formation of a nanowire using two complementary DNA conjugates, each of which has a ZZZ triplet at the 5′ termini as overhang, we demonstrate the successful formation of a nanowire by native PAGE analysis. Since native sticky ends that have three nucleotides do not serve as “glue”, ZZZ triplets with their unique glue-like properties are prime candidates for constructing DNA-based nanoarchitectures.

We synthesized various azobenzenes methylated at their ortho positions with respect to the azo bond for more effective photoregulation of DNA hybridization. Photoregulatory efficiency, evaluated from the change of T_m (ΔT_m) induced by trans–cis isomerization, was significantly improved for all ortho-modified azobenzenes compared with non-modified azobenzene due to the more stabilized trans form and the more destabilized cis form. Among the synthesized azobenzenes, 4-carboxy-2′,6′-dimethylazobenzene (2′,6′-Me-Azo), in which two ortho positions of the distal benzene ring with respect to carboxyl group were methylated, exhibited the largest ΔT_m, whereas the newly synthesized 2,6-Me-Azo (4-carboxy-2,6-dimethylazobenzene), which possesses two methyl groups on the two ortho positions of the other benzene ring, showed moderate improvement of ΔT_m. Both NMR spectroscopic analysis and computer modeling revealed that the two methyl groups on 2′,6′-Me-Azo were located near the imino protons of adjacent base pairs; these stabilized the DNA duplex by stacking interactions in the trans form and destabilized the DNA duplex by steric hindrance in the cis form. In addition, the thermal stability of cis-2′,6′-Me-Azo was also greatly improved, but not that of cis-2,6-Me-Azo. Solvent effects on the half-life of the cis form demonstrated that cis-to-trans isomerization of all the modified azobenzenes proceeded through an inversion route. Improved thermal stability of 2′,6′-Me-Azo but not 2,6-Me-Azo in the cis form was attributed to the retardation of the inversion process due to steric hindrance between lone pair electrons of the π orbital of the nitrogen atom and the methyl group on the distal benzene ring.

To increase the apparent Stokes’ shift of perylene, pyrene (donor) and perylene (acceptor) were assembled in a DNA duplex to achieve the efficient fluorescence resonance energy transfer (FRET) from pyrene to perylene. Multiple donors were introduced in the vicinity of acceptors through D-threoninol and natural base pairs were inserted between the dyes. Accordingly, donors and acceptors could be accumulated inside the DNA without forming an undesired excimer/exciplex. When two pyrene moieties were located in proximity to one perylene with one base pair inserted between them, efficient FRET occurred within the duplex. Thus, strong emission at 460 nm was observed from perylene when excited at 345 nm at which pyrene has its absorption. The apparent Stokes’ shift became as large as 115 nm with a high apparent FRET efficiency (Φ>1). However, the introduction of more than two pyrenes did not enhance the fluorescence intensity of perylene, due to the short Förster radius (R₀) of the donor pyrene. Next, this FRET system was used to enlarge the Stokes’ shift of the DNA probe, which can discriminate a one-base deletion mutant from wild type with a model system by incorporation of multiple donors into DNA. Two perylene moieties were tethered to the DNA on both sides of the intervening base, and two pyrenes were further inserted in the vicinity of the perylenes as an antenna. Hybridization of this FRET probe with a fully matched DNA allowed monomer emission of perylene when the pyrenes were excited. In contrast, excimer emission was generated by hybridization with a one-base deletion mutant. Thus, the apparent Stokes’ shift was enhanced without loss of efficiency in the detection of the deletion mutant.

To test the molecular exciton theory for heterodimeric chromophores, various heterodimers and clusters, in which two different dyes were stacked alternately, were prepared by hybridizing two oligodeoxyribonucleotides (ODNs), each of which tethered a different dye on D-threoninol at the center of the strand. NMR analyses revealed that two different dyes from each strand were stacked antiparallel to each other in the duplex, and were located adjacent to the 5′-side of a natural nucleobase. The spectroscopic behavior of these heterodimers was systematically examined as a function of the difference in the wavelength of the dye absorption maxima (Δλ_max). We found that the absorption spectrum of the heterodimer was significantly different from that of the simple sum of each monomeric dye in the single strand. When azobenzene and Methyl Red, which have λ_max at 336 and 480 nm, respectively, in the single strand (Δλ_max=144 nm), were assembled on ODNs, the band derived from azobenzene exhibited a small hyperchromism, whereas the band from Methyl Red showed hypochromism and both bands shifted to a longer wavelength (bathochromism). These hyper- and hypochromisms were further enhanced in a heterodimer derived from 4′-methylthioazobenzene and Methyl Red, which had a much smaller Δλ_max (82 nm; λ_max=398 and 480 nm in the single-strand, respectively). With a combination of 4′-dimethylamino-2-nitroazobenzene and Methyl Red, which had an even smaller Δλ_max (33 nm), a single sharp absorption band that was apparently different from the sum of the single-stranded spectra was observed. These changes in the intensity of the absorption band could be explained by the molecular exciton theory, which has been mainly applied to the spectral behavior of H- and/or J-aggregates composed of homo dyes. However, the bathochromic band shifts observed at shorter wavelengths did not agree with the hypsochromism predicted by the theory. Thus, these data experimentally verify the molecular exciton theory of heterodimerization. This coherent coupling among the heterodimers could also partly explain the bathochromicity and hypochromicity that were observed when the dyes were intercalated into the duplex.

A new photoswitch for DNA hybridization involving para-substituted azobenzenes (such as isopropyl- or tert-butyl-substituted derivatives) with L-threoninol as a linker was synthesized. Irradiation of the modified DNA with visible light led to dissociation of the duplex owing to the destabilization effect of the bulky substituent on the trans-azobenzene. In contrast, trans-to-cis isomerization (UV light irradiation) facilitated duplex formation. The direction of this photoswitching mode was entirely reversed relative to the previous system with an unmodified azobenzene on D-threoninol whose trans form turned on the hybridization, and cis form turned it off. Such reversed and reversible photoswitching of DNA hybridization was directly demonstrated by using fluorophore- and quencher-attached oligonucleotides. Furthermore, it was revealed that the cis-to-trans thermal isomerization was greatly suppressed in the presence of the complementary strand owing to the formation of the more-stable duplex in the cis form.