Sequence-specific control of gene expression by antigene and clamp oligonucleotides.

Control of gene expression at the transcriptional level can be achieved with triplex-forming oligonucleotides provided that the target sequence is accessible within the chromatin structure of cell nuclei. Using oligonucleotide-psoralen conjugates as probes we have shown that the promoter region of the gene encoding the alpha subunit of the interleukin 2 receptor and the polypurine tract of integrated HIV provirus can form sequence-specific, triple-helical complexes in cell cultures. Oligonucleotide-intercalator conjugates can inhibit transcription initiation by competing with transcription factor binding. Oligonucleotide analogues containing N3'-->P5' phosporamidate linkages form stable triple helices that are able to arrest transcription at the elongation step. A triple helix can also be formed on a single-stranded target by clamp oligonucleotides. A clamp targeted to the polypurine tract of HIV RNA is able to block reverse transcription of the viral RNA.

Triplex formation with alpha anomers of purine-rich and pyrimidine-rich oligodeoxynucleotides.

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.