An anti-parallel triple helix motif with oligodeoxynucleotides containing 2'-deoxyguanosine and 7-deaza-2'-deoxyxanthosine.

Triple helix formation of oligodeoxynucleotides (ODNs) with a 15 base pair poly-purine DNA target in the HER2 promoter was examined by footprinting analysis. 7-deaza-2'-deoxyxanthosine (dzaX) was identified as a purine analogue of thymidine (T) which forms dzaX:A-T triplets. ODNs containing 2'-deoxyguanosine (G) and dzaX were found to form triple helices in an anti-parallel orientation, with respect to the poly-purine strand of the target DNA. In comparative studies under physiological K+ and Mg++ concentrations and at pH 7.2, the ODNs containing G and dzaX showed high affinity to the target sequence while the ODNs containing G and T were not able to bind. In the absence of added monovalent salts both ODNs showed high affinity to the target sequence. The substitution of 7-deaza-2'-deoxyguanosine for G substantially decreased the capacity of the ODNs to form triple helices under physiological conditions, indicating that dzaX may be unique in its ability to enhance triple helix formation in the anti-parallel motif.     

Intramolecular triple-helix formation at (PunPyn).(PunPyn) tracts: recognition of alternate strands via Pu.PuPy and Py.PuPy base triplets.

Triple-helical DNA shows increasing potential for applications in the control of gene expression (including therapeutics) and the development of sequence-specific DNA-cleaving agents. The major limitation in this technology has been the requirement of homopurine sequences for triplex formation. We describe a simple approach that relaxes this requirement, by utilizing both Pu.PuPy and Py.PuPy base triplets to form a continuous DNA triple helix at tandem oligopurine and oligopyrimidine tracts. [Triplex formation at such a sequence has been previously demonstrated only with the use of a special 3'-3' linkage in the third strand [Horne, D. A., & Dervan, P. B. (1990) J. Am. Chem. Soc. 112, 2435-2437].] Supporting evidence is from chemical probing experiments performed on several oligonucleotides designed to form 3-stranded fold-back structures. The third strand, consisting of both purine and pyrimidine blocks, pairs with purines in the Watson-Crick duplex, switching strands at the junction between the oligopurine and oligopyrimidine blocks but maintaining the required strand polarity without any special linkage. Although Mg2+ ions are not required for the formation of Pu.PuPy base triplets, they show enhanced stability in the presence of Mg2+. In the sequences observed. A.AT triplets appear to be more stable than G.GC triplets. As expected, triplex formation is largely independent of pH unless C+.GC base triplets are required.     

Formation of DNA triple helices incorporating blocks of G.GC and T.AT triplets using short acridine-linked oligonucleotides.

We have used DNase I footprinting to assess triple helix formation at target sites containing the sequences A6G6.C6T6 and G6A6.T6C6. These sequences can be recognized by the acridine-linked oligopyrimidines Acr-T5C5 and Acr-C5T5 respectively at low pH, using well-characterised T.AT and C+.GC triplets. At pH 7.5 A6G6.C6T6 is specifically bound by Acr-G5T5, utilising G.GC and T.AT triplets in which the third strand runs antiparallel to the purine strand of the duplex. This interaction requires the presence of magnesium ions. No interaction was detected with Acr-T5G5, an oligonucleotide designed to form parallel G.GC and T.AT triplets. In contrast neither Acr-T5G5 nor Acr-G5T5 produced DNase I footprints with the target sequence G6A6.T6C6. These results suggest that, in an antiparallel R.RY triple helix, the T.AT triplet is weaker than the G.GC triplet. We find no evidence for the formation of structures containing parallel G.GC triplets.     

The influence of single base triplet changes on the stability of a pur.pur.pyr triple helix determined by affinity cleaving.

The influence of sixteen base triplet changes at a single position within a pur.pur.pyr triple helix was examined by affinity cleaving. For the 15 base pair target site studied here, G.GC, A.AT and T.AT triplets stabilize a triple helix to a greater extent than the other 13 natural triplets (pH = 7.4, 25 degrees C). Weaker interactions were detected for the C.AT, A.GC and T.CG triplets. The absence of specific, highly stabilizing interactions between third strand bases and the CG or TA base pairs demonstrates a current sequence limitation to formation of this structure. Models for the two dimensional base triplet interactions for all possible 16 natural triplets are presented.     

Uranyl photofootprinting of triple helical DNA.

Two triple helix structures (15-mers containing only T.A-T triplets or containing mixed T.A-T and C.G-C triplets) have been studied by uranyl mediated DNA photocleavage to probe the accessibility of the phosphates of the DNA backbone. Whereas the phosphates of the pyrimidine strand are at least as accessible as in double stranded DNA, in the phosphates of the purine strand are partly shielded and more so at the 5'-end of the strand. With the homo A/T target increased cleavage is observed towards the 3'-end on the pyrimidine strand. These results show that the third strand is asymmetrically positioned along the groove with the tightest triple strand double strand interactions at the 5'-end of the third strand. The results also indicate that homo-A versus mixed A/G 'Hoogsteen-triple helices' have different structures.     

Parallel intramolecular DNA triple helix with G and T bases in the third strand stabilized by Zn(2+) ions

We present evidence of formation of an intramolecular parallel triple helix with T•A.T and G•G.C base triplets (where • represents the hydrogen bonding interaction between the third strand and the duplex while . represents the Watson–Crick interactions which stabilize the duplex). The third GT strand, containing seven GpT/TpG steps, targets the polypurine sequence 5′-AGG-AGG-GAG-GAG-3′. The triple helix is obtained by the folding back twice of a 36mer, formed by three dodecamers tethered by hydroxyalkyl linkers (-L-). Due to the design of the oligonucleotide, the third strand orientation is parallel with respect to the polypurine strand. Triple helical formation has been studied in concentration conditions in which native gel electrophoresis experiments showed the absence of intermolecular structures. Circular dichroism (CD) and UV spectroscopy have been used to evidence the triplex structure. A CD spectrum characteristic of triple helical formation as well as biphasic UV and CD melting curves have been obtained in high ionic strength NaCl solutions in the presence of Zn²⁺ ions. Specific interactions with Zn²⁺ ions in low water activity conditions are necessary to stabilize the parallel triplex.     

Use of a pyrimidine nucleoside that functions as a bidentate hydrogen bond donor for the recognition of isolated or contiguous G-C base pairs by oligonucleotide-directed triplex formation.

Synthesis of the nucleoside building block of the 6-keto derivative of 2'-deoxy-5-methylcytidine (m5oxC) as an analog of an N3-protonated cytosine derivative is described. A series of 15mer oligonucleotides containing either four or six m5oxC residues has been prepared by chemical synthesis. Complexation of the 15 residue oligonucleotides with target 25mer duplexes results in DNA triplexes containing T-A-T and m5oxC-G-C base triplets. When the m5oxC-G-C base triplets are present in sequence positions that alternate with TAT base triplets, DNA triplexes are formed with Tm values that are pH independent in the range 6.4-8.5. A 25mer DNA duplex containing a series of five contiguous G-C base pairs cannot be effectively targeted with either m5C or M5oxC in the third strand. In the former case charge-charge repulsion effects likely lead to destabilization of the complex, while in the latter case ineffective base stacking may be to blame. However, if the m5C and M5oxC residues are present in the third strand in alternate sequence positions, then DNA triplexes can be formed with contiguous G-C targets even at pH 8.0.     

Structural heterogeneity in intramolecular DNA triple helices

Oligodeoxynucleotides designed to form intramolecular triple helices are widely used as model systems in thermodynamic and structural studies. We now report results from UV, Raman and NMR experiments demonstrating that the strand polarity, which also determines the orientation of the connecting loops, has a considerable impact on the formation and stability of pyr x pur x pyr triple helices. There are two types of monomolecular triplexes that can be defined by the location of their purine tract at either the 5'- or 3'-end of the sequence. We have examined four pairs of oligonucleotides with the same base composition but with reversed polarity that can fold into intramolecular triple helices with seven base triplets and two T4 loops under appropriate conditions. UV spectroscopic monitoring of thermal denaturation indicates a consistently higher thermal stability for the 5'-sequences at pH 5.0 in the absence of Mg2+ ions. Raman spectra provide evidence for the formation of triple helices at pH 5 for oligomers with purine tracts located at either the 5'- or 3'-end of the sequence. However, NMR measurements reveal considerable differences in the secondary structures formed by the two types of oligonucleotides. Thus, at acidic pH significant structural heterogeneity is observed for the 3'-sequences. Employing selectively 15N-labeled oligomers, NMR experiments indicate a folding pattern for the competing structures that at least partially changes both Hoogsteen and Watson-Crick base-base interactions.     

A computational and experimental study of the bending induced at a double-triple helix junction.

We have studied the conformation of a 17 base-pair homopyrimidine.homopurine triple helix formed on a fragment of duplex DNA derived from Simian Virus SV40. Gel retardation assays indicate that an 80 base-pair fragment has an altered conformation when the triple helix is formed, which is most likely to result from an induced bend in the DNA. Investigation of the detailed conformation of the double helix-triple helix junctions has been performed by means of molecular modelling. Bending on the 5' and 3' sides of the third strand oligonucleotide are not located at equivalent positions with respect to the junctions, which is explained in terms of base stacking. The junction effects on DNA structure, induced by the requirement for cytosine protonation in the Hoogsteen-bonded strand to form CGC+ base triplets, are also discussed.     

Influence of pH on the equilibrium association constants for oligodeoxyribonucleotide-directed triple helix formation at single DNA sites.

The energetics of oligodeoxyribonucleotide-directed triple helix formation for the pyrimidine.purine.pyrimidine structural motif were determined over the pH range 5.8-7.6 at 22 degrees C (100 mM Na+ and 1 mM spermine) using quantitative affinity cleavage titration. The equilibrium binding constants for 5'-TTTTTCTCTCTCTCT-3' (1) and 5'-TTTTTm5CTm5CTm5CTm5CTm5CT-3' (2, m5C is 2'-deoxy-5-methylcytidine) increased by 10- and 20-fold, respectively, from pH 7.6 to 5.8, indicating that the corresponding triple-helical complexes are stabilized by 1.4 and 1.7 kcal.mol-1, respectively, at the lower pH. Replacement of the five cytosine residues in 1 with 5-methylcytosine residues to yield 2 affords a stabilization of the triple helix by 0.1-0.4 kcal.mol-1 over the pH range 5.8-7.6. An analysis of these data in terms of a quantitative model for a general pH-dependent equilibrium transition revealed that pyrimidine oligonucleotides with cytidine and 5-methylcytidine form local triple-helical structures with apparent pKa's of 5.5 (C+GC triplets) and 5.7 (m5C+GC triplets), respectively, and that the oligonucleotides should bind to single sites on large DNA with apparent affinity constants of approximately 10(6) M-1 even above neutral pH.     

Thermodynamics of triple helix formation: spectrophotometric studies on the d(A)10.2d(T)10 and d(C+3T4C+3).d(G3A4G3).d(C3T4C3) triple helices.

We have stabilized the d(A)10.2d(T)10 and d(C+LT4C+3).d(G3A4G3).d(C3T4C3) triple helices with either NaCl or MgCl2 at pH 5.5. UV mixing curves demonstrate a 1:2 stoichiometry of purine to pyrimidine strands under the appropriate conditions of pH and ionic strength. Circular dichroic titrations suggest a possible sequence-independent spectral signature for triplex formation. Thermal denaturation profiles indicate the initial loss of the third strand followed by dissociation of the underlying duplex with increasing temperature. Depending on the base sequence and ionic conditions, the binding affinity of the third strand for the duplex at 25 degrees C is two to five orders of magnitude lower than that of the two strands forming the duplex. Thermodynamic parameters for triplex formation were determined for both sequences in the presence of 50 mM MgCl2 and/or 2.0 M NaCl. Hoogsteen base pairs are 0.22-0.64 kcal/mole less stable than Watson-Crick base pairs, depending on ionic conditions and base composition. C+.G and T.A Hoogsteen base pairs appear to have similar stability in the presence of Mg2+ ions at low pH.     

Stable triple helices are formed upon binding of RNA oligonucleotides and their 2'-O-methyl derivatives to double-helical DNA.

Pyrimidine oligoribonucleotides bind to the major groove of double-helical DNA at homopurine.homopyrimidine sequences. They recognize Watson-Crick base pairs by forming T.A x U and C.G x C base triplets via Hoogsteen hydrogen bonding. The stability of these triple helices is much higher than that of triple helices formed by oligodeoxyribonucleotides as shown by an increase of the temperature at which half-dissociation of the third strand occurs. When the 2'-hydroxyl group of ribose moieties is replaced by 2'-O-methyl substituent, triple helix stability is further increased.     

Triplex formation at physiological pH by 5-Me-dC-N4-(spermine) [X] oligodeoxynucleotides: non protonation of N3 in X of X*G:C triad and effect of base mismatch/ionic strength on triplex stabilities.

Oligodeoxynucleotide (ODN) directed triplex formation has therapeutic importance and depends on Hoogsteen hydrogen bonds between a duplex DNA and a third DNA strand. T*A:T triplets are formed at neutral pH and C+*G:C are favoured at acidic pH. It is demonstrated that spermine conjugation at N4 of 5-Me-dC in ODNs 1-5 (sp-ODNs) imparts zwitterionic character, thus reducing the net negative charge of ODNs 1-5. sp-ODNs form triplexes with complementary 24mer duplex 8:9 show foremost stability at neutral pH 7.3 and decrease in stability towards lower pH, unlike the normal ODNs where optimal stability is found at an acidic pH 5.5. At pH 7.3, control ODNs 6 and 7 carrying dC or 5-Me-dC, respectively, do not show any triple helix formation. The stability order of triplex containing 5-Me-dC-N4-(spermine) with normal and mismatched duplex was found to be X*G:C approximately X*A:T > X*C:G > X*T:A. The hysteresis curve of sp-ODN triplex 3*8:9 indicated a better association with complementary duplex 8:9 as compared to unmodified ODN 6 in triplex 6*8:9. pH-dependent UV difference spectra suggest that N3 protonation is not a requirement for triplex formation by sp-ODN and interstrand interaction of conjugated spermine more than compensates for loss in stability due to absence of a single Hoogsteen hydrogen bond. These results may have importance in designing oligonucleotides for antigene applications.     

Parallel and antiparallel G*G.C base triplets in pur*pur.pyr triple helices formed with (GA) third strands.

Triple helices with G*G.C and A*A.T base triplets with third GA strands either parallel or antiparallel with respect to the homologous duplex strand have been formed in presence of Na (+) or Mg(2+) counterions. Antiparallel triplexes are more stable and can be obtained even in presence of only monovalent Na(+) counterions. A biphasic melting has been observed, reflecting third strand separation around 20 degrees C followed by the duplex -> coil transition around 63 degrees C. Parallel triplexes are far less stable than the antiparallel ones. Their formation requires divalent ions and is observed at low temperature and in high concentration conditions. Different FTIR signatures of G*G.C triplets in parallel and antiparallel triple helices with GA rich third strands have been obtained allowing the identification of such base triplets in triplexes formed by nucleic acids with heterogeneous compositions. Only S-type sugars are found in the antiparallel triplex while some N-type sugar conformation is detected in the parallel triplex.     

Structural constraints regulating triple helix formation by A-tracts

The study concerns the propensity of triple helix formation by different DNA oligonucleotides containing long A-tracts with and without flanking GxC base pairs in order to probe the role of length of the A-tract and the flanking sequences. From nuclear magnetic resonance (NMR) studies of imino proton spectra and circular dichroism (CD) spectroscopy of samples composed of potential triplex forming strand sequences in correct stoichiometries, we have concluded that 8-mer A-tracts flanked by GxC base pairs exert significant steric hindrance to triple helix formation. When as much as 50 mM Mg2+ was added, no triple helix formation was observed in these samples. In contrast, open-ended 8-mer A-tracts formed triplex with the corresponding two T8 strands under relatively mild ionic conditions (100 mM Na+). Moreover, the shorter the length of the A-tract, the less is the hindrance to form a triple helix.     

Pyrimidine morpholino oligonucleotides form a stable triple helix in the absence of magnesium ions

Oligonucleotides can be used as sequence-specific DNA ligands by forming a local triple helix. In order to form more stable triple-helical structures or prevent their degradation in cells, oligonucleotide analogues that are modified at either the backbone or base level are routinely used. Morpholino oligonucleotides appeared recently as a promising modification for antisense applications. We report here a study that indicates the possibility of a triple helix formation with a morpholino pyrimidine TFO and its comparison with a phosphodiester and a phosphoramidate oligonucleotide. At a neutral pH and in the presence of a high magnesium ion concentration (10 mM), the phosphoramidate oligomer forms the most stable triple helix, whereas in the absence of magnesium ion but at a physiological monovalent cation concentration (0.14 M) only morpholino oligonucleotides form a stable triplex. To our knowledge, this is the first report of a stable triple helix in the pyrimidine motif formed by a noncharged oligonucleotide third strand (the morpholino oligonucleotide) and a DNA duplex. We show here that the structure formed with the morpholino oligomer is a bona fide triple helix and it is destabilized by high concentrations of potassium ions or divalent cations (Mg(2+)).     

Strand orientation of [alpha]-oligodeoxynucleotides in triple helix structures: dependence on nucleotide sequence.

The aims of the present theoretical study of the conformations of [alpha]-oligodeoxynucleotides forming triple helices with DNA duplexes are to understand the structural and energetic factors involved in [alpha]-triple helix formation by means of energy minimization, and to explain the experimentally observed dependence of strand orientation on the nucleotide sequence. It is found that the energetically preferred orientation of the [alpha]-oligonucleotide with respect to the homopurine strand depends on the sequence of the homopurine.homopyrimidine tracts. This is a consequence of the structural heteromorphism of base triplets in the intrinsically more stable reverse Hoogsteen hydrogen bonding configuration. Practical rules are proposed for determining the orientation of the nuclease-resistant [alpha]-oligodeoxynucleotide strand which will form the most stable triple helix.     

Chemical modification of pyrimidine TFOs: effect on i-motif and triple helix formation

In order to form more stable triple helical structures or to prevent their degradation in cells, oligonucleotide analogs are routinely used, either in the backbone or among the bases. The target sequence chosen for this study is a 16-base-long oligopurine-oligopyrimidine region present in the human neurotrophin 4/5 gene. Seven different chemical modifications were tested for their effect on (i) triple helix formation and (ii) i-DNA stability. i-DNA is a tetrameric structure involving hemiprotonated C x C+ base pairs, which may act as a competing structure for triplex formation, especially in the case of a cytosine-rich third strand. At acid pH, oligophosphoramidates formed the most stable triple helix, whereas oligonucleotides including 5-propynyl-dU formed a stable i-motif which precluded triplex formation. Only two candidates stabilized triple helices at neutral pH: oligonucleotides with phosphoramidate linkage and phosphodiester oligonucleotides containing 5-methyl-dC and 5-propynyl-dU.     

Spectroscopic studies of chimeric DNA-RNA and RNA 29-base intramolecular triple helices.

Fourier transform infrared (FTIR), UV absorption and exchangeable proton NMR spectroscopies have been used to study the formation and stability of two intramolecular pH-dependent triple helices composed by a chimeric 29mer DNA-RNA (DNA double strand and RNA third strand) or by the analogous 29mer RNA. In both cases decrease of pH induces formation of a triple helical structure containing either rU*dA.dT and rC+*dG.dC or rU*rA.rU and rC+*rG.rC triplets. FTIR spectroscopy shows that exclusively N-type sugars are present in the triple helix formed by the 29mer RNA while both N- and S-type sugars are detected in the case of the chimeric 29mer DNA-RNA triple helix. Triple helix formation with the third strand RNA and the duplex as DNA appears to be associated with the conversion of the duplex part from a B-form secondary structure to one which contains partly A-form sugars. Thermal denaturation experiments followed by UV spectroscopy show that a major stabilization occurs upon formation of the triple helices. Monophasic melting curves indicate a simultaneous disruption of the Hoogsteen and Watson-Crick hydrogen bonds in the intramolecular triplexes when the temperature is increased. This is in agreement with imino proton NMR spectra recorded as a function of temperature. Comparison with experiments concerning intermolecular triplexes of identical base and sugar composition shows the important role played by the two tetrameric loops in the stabilization of the intramolecular triple helices studied.