Tethered naphthalene diimide intercalators enhance DNA triplex stability.

Naphthalene diimides function as effective intercalators and when tethered to the 5'-terminus of a pyrimidine-rich oligonucleotide can contribute significantly to the overall stabilization of DNA triplexes. This stabilization can be further enhanced by alterations to the linker tethering the DNA sequence and the intercalator. Less flexible linkers, and particularly one with a phenyl ring present, appear to permit the stabilization afforded by the bound intercalator to be transferred more effectively to the three-stranded complex. The conjugate containing the phenyl linker exhibits a T(M) value that is increased by 28 degrees C relative to the unconjugated triplex. That the linker itself contributes to the observed stabilization is clear since introduction of the phenyl linker increases the observed T(M) by 11 degrees C relative to a simple flexible linker.

Long-range guanine oxidation in DNA restriction fragments by a triplex-directed naphthalene diimide intercalator.

Naphthalene diimide (NDI), a powerful oxidant that binds avidly to DNA by intercalation, is seen to damage the 5' guanine of 5'-GG-3' sites by photoactivated charge transport through DNA. When covalently tethered to the center of a triplex-forming oligonucleotide and delivered by triplex formation within a pyrimidine.purine-pyrimidine motif to a specific site on a restriction fragment, NDI can photooxidize guanine over at least 25-38 bp in each direction from the site of binding. Charge migration occurs in both directions from the NDI intercalator and on both DNA strands of the target, but the oxidation is significantly more efficient to the 3' side of the triplex. NDI and octahedral rhodium intercalators, when tethered directly to the 5' terminus of the triplex-forming strand as opposed to the center, generate significant amounts of oxidative damage only in the immediate vicinity of the intercalation site. Given that long-range charge transport depends on DNA stacking, these results suggest that the base stack is distorted at the 5' end of the triplex region in the duplex-triplex junction. Targeting of photooxidative damage by triplex formation extends our previous studies of long-range charge transport to significantly longer DNA sequences through a strategy that does not require covalent attachment of the photooxidant to the DNA being probed. Moreover, triplex targeting of oxidative damage provides for the first time a typical distance distribution for genomic charge transport of approximately 200 A around the oxidant.

Tethered naphthalene diimide-based intercalators for DNA triplex stabilization.

The synthesis and triplex stabilizing properties of oligodeoxyribonucleotides functionalized at the 5'- and/or 3'-termini with a naphthalene diimide-based (NDI) intercalator is described. The NDI intercalator was prepared in a single step from the corresponding dianhydride and was attached to the 5'-terminus of an oligodeoxyribonucleotide following a reverse coupling procedure. The DMT protecting group was removed and the sequence phosphitylated to generate the phosphoramidite derivative on the 5'-terminus of the support-bound oligodeoxyribonucleotide. The NDI intercalator with a free hydroxyl was then added in the presence of tetrazole. Attachment of the NDI to the 3'-terminus relied upon a tethered amino group that could be functionalized first with the naphthalene dianhydride, which was subsequently converted to the diimide. Using both procedures, an oligonucleo-tide conjugate was prepared having the NDI intercalator at both the 5'- and 3'-termini. Thermal denaturation studies were used to determine the remarkable gain in stability for triplexes formed when the NDI-conjugated oligonucleotide was present as the third strand in the complex.

Synthesis and triplex forming properties of pyrimidine derivative containing extended functionality.

Two pyrimidine nucleosides have been synthesized containing extended hydrogen bonding functionality. In one case the side chain is based upon semicarbazide and in the second monoacetylated carbohydrazide was employed. DNA sequences could be prepared using both analogue nucleosides in a reverse coupling protocol, and provided that the normal capping step was eliminated and that the iodine-based oxidizing solution was replaced with one based upon 10-camphorsulfonyl oxaziridine. Both derivatives exhibited moderate effects in targeting selectively C-G base pairs embedded within a polypurine target sequence.