Modulation of Cm/T, G/A, and G/T triplex stability by conjugate groups in the presence and absence of KCl.

Apparent equilibrium association constants were determined by gel mobility shift analysis for triple strand formation between a duplex target containing a 21 base long A-rich homopurine run and several end-modified C(m)/T (pyrimidine motif; C(m) = 5-methylcytosine), G/A (purine motif), and G/T (purine-pyrimidine motif) triplex-forming oligonucleotides (TFOs). Incubations were carried out for 24 h at 37 degrees C in 20 mM HEPES, pH 7.2, 10 mM MgCl2, and 1 mM spermine. The purine motif triplex was the most stable (Ka = 6.2 x 10(8) M-1) even though the TFO self-associated as a linear duplex. Conjugation of a terminal hexanol or cholesterol group to the G/A-containing TFO reduced triplex stability by 1.6- or 13-fold, whereas an aminohexyl group or intercalating agent (acridine or psoralen) increased triplex stability by 1.3- or 13-fold. These end groups produced similar effects in C(m)/T and G/T triplexes, although the magnitude of the effect sometimes differed. Addition of 140 mM KCl to mimic physiological conditions decreased stability of the G/A triplex by 1900-fold, making it less stable than the C(m)/T triplex. The inhibitory effect of KCl on G/A triplex formation could be partially compensated for by conjugating the TFO to an intercalating agent (30-350-fold stabilization) or by adding the triplex selective intercalator coralyne (1000-fold stabilization). Although the G/T triplex responded similarly to these agents, the stability of the C(m)/T triplex was unaffected by the presence of coralyne and was only enhanced 1.4-2.8-fold when the TFO was linked to an intercalating agent. In physiological buffer supplemented with 40 microM coralyne, the G/A triplex (Ka = 3.0 x 10(8) M-1) was more stable than the C(m)/T and G/T triplexes by factors of 300 and 12, respectively.

Oligonucleotides containing 2-aminoadenine and 2-thiothymine act as selectively binding complementary agents.

A pair of complementary oligodeoxynucleotides (ODNs) uniformly substituted with 2-amino-adenine (A') in place of adenine and 2-thiothymine (T') in place of thymine did not hybridize to each other but did form very stable hybrids with unmodified complementary ODNs. These unusual properties were a consequence of the hydrogen-bonding properties of the two base analogs. Thermal denaturation studies of short duplexes which contained these bases demonstrated that the A'-T and A-T' doublets formed stable base pairs whereas the A'-T' doublet acted like a mismatch. Complementary ODNs substituted with these base analogs are referred to as SBC or selectively binding complementary ODNs. When used as a pair, these single-stranded ODNs invaded the ends of homologous duplexes and formed stable three-arm junctions under conditions where unmodified ODNs failed to give a product. SBC ODNs have a fundamental thermodynamic advantage in hybridizing to short segments of double-stranded nucleic acid and represent a new approach for the design of oligomeric probes and antisense agents. Many secondary structure features present in long single-stranded nucleic acids should be accessible to these reagents.