A 3-azidoproflavine derivative was covalently linked to the 5'-end of an octathymidylate synthesized with the [alpha]-anomers of the nucleoside. Two target nucleic acids were used for this substituted oligo-[alpha]-thymidylate: a 27-mer single-stranded DNA fragment containing an octadeoxyadenylate sequence and a 27-mer duplex containing eight contiguous A.T base pairs with all adenines on the same strand. Upon visible light irradiation the octa-[alpha]-thymidylate was photocrosslinked to the single-stranded 27-mer. Chain breaks were induced at the crosslinked sites upon piperidine treatment. From the location of the cleavage sites on the 27-mer sequence it was concluded that a triple helix was formed by the azidoproflavine-substituted oligo-[alpha]-thymidylate with its complementary oligodeoxyadenylate sequence. When the 27-mer duplex was used as a substrate cleavage sites were observed on both strands after piperidine treatment of the irradiated sample. They were located at well defined positions which indicated that the octathymidylate was bound to the (dA)8.(dT)8 sequence in parallel orientation with respect to the (dA)8-containing strand. Specific binding of the [alpha]-octathymidylate involved local triple strand formation with the duplex (dA)8.(dT)8 sequence. This result shows that it is possible to synthesize sequence-specific molecules which specifically bind oligopurine-oligopyrimidine sequences in double-stranded DNA via recognition of the major groove hydrogen bonding sites of the purines.
A photocrosslinking reagent (p-azidophenacyl) was covalently linked to an octathymidylate synthesized with either the natural ((3) anomer of thymidine or the synthetic (a) anomer. The oligothymidylate was further substituted by an acridine derivative to stabilize the hybrid formed with a complementary octadeoxyadenylate sequence via intercalation. A single-stranded 27-mer containing a (dA)8 sequence and a 27-mer duplex containing a (dA-dT)8 sequence were used as targets. Upon UV irradiation, photocrosslinking of the octathymidylate to its target sequence was observed, generating bands that migrated more slowly in denaturing gels. In the 27-mer duplex, both strands were photocrosslinked to the octathymidylate. Upon alkaline treatment of the irradiated samples, cleavage of the 27-mers was observed at specific sites. These reactions were analyzed at different salt concentrations. The location of the cleavage sites allowed us to demonstrate the following. (i) Both a and (3 oligothymidylates can recognize a DNA double helix containing an oligo(dA)-oligo(dT) sequence; the oligothymidylate binds to the major groove of DNA in a parallel orientation with respect to the adenine-containing strand of the DNA double helix. (ii) a oligothymidylates form helices with a complementary singlestranded oligodeoxyadenylate; the two strands have a parallel orientation independently of whether or not an intercalating agent is attached to the oligothymidylate. (iii) At low salt concentration, (3 oligothymidylates form a double helix with an oligodeoxyadenylate in which, as expected, the two strands are antiparallel; at high salt concentration, a triple helix is formed in which the second oligothymidylate is oriented parallel to the adenine-containing strand. These results show that it is possible to recognize an oligopurine-oligopyrimidine sequence in a DNA double helix via local triple-helix formation and to target photochemical reactions to specific sequences in both double-stranded and single-stranded nucleic acids.
An octathymidylate covalently linked via its 3'-end to an acridine derivative inhibited the cytopathic effect of Simian Virus SV40 on CV-1 cells in culture. Control experiments revealed that this effect was virus-specific and did not arise as a result of oligonucleotide degradation by nucleases. A photoactive probe was covalently attached to the 5'-end of the oligonucleotide-acridine conjugate. Upon UV-irradiation, photocrosslinking was shown to occur at the A. T-rich region within the viral origin of replication. A local triple helix can form at moderate salt concentrations with two octathymidylate-acridine conjugates bound to the octaadenylate sequence. Alternatively the octathymidylate-acridine conjugate can bind to the major groove of duplex DNA forming a local triple helix. Different mechanisms are discussed to explain the inhibition of viral DNA replication.
Nuclease-resistant alpha anomers of pyrimidine-rich CT- and purine-rich GA- and GT-containing oligonucleotides were investigated for their triplex-forming potential and compared with their corresponding nuclease-sensitive beta anomers. Both 23mer CT-alpha and 23mer CT-beta had quite similar triplex binding affinities. Synthetic 23mer GT-alpha oligonucleotides were capable of triplex formation with binding affinities slightly lower than corresponding 23mer GT-beta oligonucleotides. The orientation of third strand GT-alpha binding was parallel to the purine strand of the duplex DNA target, whereas the orientation of third strand GT-beta binding was found to be antiparallel. Triplex formation with both GT oligonucleotides showed the typical dependence on magnesium and temperature. In contrast, 23mer GA-alpha oligonucleotides did not support triplex formation in either orientation under a variety of experimental conditions, whereas the corresponding 23mer GA-beta oligonucleotides demonstrated strong triplex formation in the antiparallel orientation. GA-alpha oligonucleotides covalently conjugated to acridine were similarly unable to demonstrate triplex formation. GA-alpha oligonucleotides, in contrast to GT-alpha oligonucleotides, were capable of self-association, detectable by gel retardation and UV spectroscopy, but competing self-association could not fully account for the lack of triplex formation. Thus for in vivo triplex gene regulation strategies using GT oligonucleotides the non-natural alpha anomer may be a feasible alternative to the natural beta anomer, allowing for a comparable degree of triplex formation without rapid cellular degradation. However, alpha anomeric inversion does not appear to be a feasible alternative in applications involving GA oligonucleotides.
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