Parallel and antiparallel A*A-T intramolecular triple helices.

Intramolecular triple helices have been obtained by folding back twice oligonucleotides formed by decamers bound by non-nucleotide linkers: dA10-linker-dA10-linker-dT10 and dA10-linker-dT10-linker-dA10. We have thus prepared two triple helices with forced third strand orientation, respectively antiparallel (apA*A-T) and parallel (pA*A-T) with respect to the adenosine strand of the Watson-Crick duplex. The existence of the triple helices has been shown by FTIR, UV and fluorescence spectroscopies.

Sugar conformations in DNA and RNA-DNA triple helices determined by FTIR spectroscopy: role of backbone composition.

We have studied the effect of the nature of the third-strand sugar (ribose or deoxyribose) on the geometry and stability of triple helices with a pyrimidine motif targeting the polypurine tract of the Friend murine retrovirus. Comparison between triplexes containing a third strand formed by a deoxy 13mer d(TCT5C6), the same oligomer but with C5-methylated cytosines d(T5meCT5(5me)C6), and an analogous modified 13mer RNA 2'Omer(UCU5C6) shows that the sugar conformations of the different triple helices, determined by FTIR spectroscopy, differ depending on nature of the third-strand sugar. Pyrimidine*purine-pyrimidine triple-helix formation with the third-strand RNA and the duplex as DNA appears to be associated with a conversion of the duplex part from a B-form secondary structure with S-type sugars to a geometry in which the polypurine strand sugars adopt an N-type conformation.

Conformations of three-stranded DNA structures formed in presence and in absence of the RecA protein.

Using FTIR and UV spectroscopies, we have studied the structures of three-stranded DNA complexes (TSC) having two identical strands, containing all four bases, in parallel orientation. In the first system, an intermolecular TSC is formed by the addition of the third strand (ssDNA) previously coated with RecA protein to an hairpin duplex (dsDNA), in presence of ATP gamma S. In the second one, the formation of an intramolecular triplex is forced by folding back twice on itself an oligonucleotide.

FTIR study of a nonclassical dT10*dA10-dT10 intramolecular triple helix.

Many early investigations on triple helices have been devoted to the study of the triplex formed by dT*dA-dT base triplets in which the third strand is oriented parallel to the dA strand. We now describe an intramolecular triple helix with dT*dA-dT base triplets in which the pyrimidine third strand is oriented antiparallel, formed by folding back twice the tridecamer dT10-linker-dA10-linker-dT10 (linker = pO(CH2CH2O)3p). Third-strand base pairing to the target strand, sugar conformation, and thermal denaturation of the triplex have been studied by Fourier transform infrared spectroscopy.

A triple helix obtained by specific recognition of all 4 bases in duplex DNA can adopt a collapsed or an extended form.

It has been proposed that during homologous recombination promoted by RecA DNA triple helices can be formed between a Watson Crick duplex and a homologous third strand without any sequence constraint. A triple helix, obtained by targeting the d(AGTTAGCATG) sequence containing all 4 bases, in which both homologous strands are oriented in a parallel direction with respect to each other, stabilized by addition of Mn2+ ions has been studied by UV and FTIR spectroscopies. We have characterized the sugar conformations of this triplex.