Conformational diversity versus nucleic acid triplex stability, a combinatorial study.

The stability of a triple helix formed between a DNA duplex and an incoming oligonucleotide strand strongly depends on the solvent conditions and on intrinsic chemical and conformational factors. Attempts to increase triple helix stability in the past included chemical modification of the backbone, sugar ring, and bases in the third strand. However, the predictive power of such modifications is still rather poor. We therefore developed a method that allows for rapid screening of conformationally diverse third strand oligonucleotides for triplex stability in the parallel pairing motif to a given DNA double helix sequence. Combinatorial libraries of oligonucleotides of the requisite (fixed) base composition and length that vary in their sugar unit (ribose or deoxyribose) at each position were generated. After affinity chromatography against their corresponding immobilized DNA target duplex, utilizing a temperature gradient as the selection criterion, the oligonucleotides forming the most stable triple helices were selected and characterized by physicochemical methods. Thus, a series of oligonucleotides were identified that allowed us to define basic rules for triple helix stability in this conformationally diverse system. It was found that ribocytidines in the third strand increase triplex stability relative to deoxyribocytidines independently of the neighboring bases and position along the strand. However, remarkable sequence-dependent differences in stability were found for (deoxy)thymidines and uridines.     

Evaluation of some properties of a phosphorodithioate oligodeoxyribonucleotide for antisense application.

An all phosphorodithioate oligodeoxyribonucleotide (PS2; 17-mer) complementary to the coding region of the rabbit beta-globin mRNA was compared with the normal (PO2) and phosphorothioate (POS) oligonucleotide of the same size and sequence with respect to physicochemical properties and antisense activity in cell-free systems. The melting temperature (Tm) of the PS2-cDNA duplex was reduced by 17 degrees C relative to the PO2-cDNA duplex, compared to 11 degrees C for the POS-cDNA duplex, suggesting a decreased stability of the duplex with an increasing sulfur substitution. Like the POS-derivative, the PS2 oligonucleotide is quite stable against exonucleases, but these modified oligonucleotides showed different stability towards endonucleases and also towards different sub-cellular fractions of MCF-7 cells. During in vitro protein binding studies, the PS2 oligonucleotide showed similar binding (10-20%) to that of the PO2 oligonucleotide, while the POS oligonucleotide bound 60%. In cell-free translation, the PS2 oligonucleotide produced slightly higher specific translation inhibition of rabbit beta-globin mRNA compared to that of the PO2 oligonucleotide, and this was true only at concentration below 2 mM. The POS-derivative, except at 10 mM concentration, always showed higher translation arrest of the rabbit beta-globin mRNA compared to that of the other two oligonucleotides. The present study suggests that the PS2 oligonucleotide offers very little advantage over the POS oligonucleotide for use as an antisense analog.     

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.     

Self-replication of chemical systems based on recognition within a double or a triple helix: a realistic hypothesis.

A scenario is proposed by which non-enzymatic self-replication of short RNA molecules could occur. The hypothesis is illustrated for the self-replication of an oligopyrimidine (Y) strand. The successful replication of Y requires a series of plausible steps. The first, experimentally feasible, step involves the template-directed polynucleotide synthesis, based on Watson-Crick base pairing, of an oligopurine (R) strand using Y as the template, and chemically activated mononucleotides as the building blocks. This step will result in the formation of an oligopyrimidine.oligopurine (YR) double helix. The second step requires the use of the double helix as the template for the synthesis of a second oligopyrimidine (Y') strand from activated pyrimidine monomers. This synthesis could be facilitated by the binding of the monopyrimidines in the major groove of the YR double helix, via Hoogsteen-type base pairing with the R strand, establishing in that sense triple helix recognition. This step, if successful, should result in the formation of a new strand, Y', that runs parallel to the oligopurine strand. Y' differs from Y in that all 3'-5' phosphodiester linkages in Y are replaced by 5'-3' linkages in Y'. The resulting triple helix (YRY') is in dynamic equilibrium with YR and free Y'. In subsequent steps, unassociated Y' directs the synthesis of the complementary oligopurine (R') strand forming a new double helix Y'R' that may direct the synthesis of an oligopyrimidine strand, Y, that is expected to be identical to the first strand that started the whole sequence. An attempt is made to generalize the above hypothesis to mixed oligonucleotides containing all four bases and identify the limitations of this hypothesis.     

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.     

Sequence specificity in triple-helix formation: experimental and theoretical studies of the effect of mismatches on triplex stability

The specificity of a homopyrimidine oligonucleotide binding to a homopurine-homopyrimidine sequence on double-stranded DNA was investigated by both molecular modeling and thermal dissociation experiments. The presence of a single mismatched triplet at the center of the triplex was shown to destabilize the triple helix, leading to a lower melting temperature and a less favorable energy of interaction. A terminal mismatch was less destabilizing than a central mismatch. The extent of destabilization was shown to be dependent on the nature of the mismatch. Both single base-pair substitution and deletion in the duplex DNA target were investigated. When a homopurine stretch was interrupted by one thymine, guanine was the least destabilizing base on the third strand. However, G in the third strand did not discriminate between a C.G and an A.T base pair. If the stretch of purines was interrupted by a cytosine, the presence of pyrimidines (C or T) in the third strand yielded a less destabilizing effect than purines. This study shows that oligonucleotides forming triple helices can discriminate between duplex DNA sequences that differ by one base pair. It provides a basis for the choice of antigene oligonucleotide sequences targeted to selected sequences on duplex DNA.     

Effect of a 5'-phosphate on the stability of triple helix.

An effect of 5'-phosphorylation on the stability of triple helical DNA containing pyrimidine:purine:pyrimidine strands has been demonstrated by both gel electrophoresis and UV melting. A 5'-phosphate on the purine-rich middle strand of a triple helix lowers the stability of triple helix formation by approximately 1 kcal/mol at 25 degrees C. The middle strand is involved in both Watson-Crick and Hoogsteen base pairing. In contrast, a 5'-phosphate on the pyrimidine-rich strands, which are involved in either Watson-Crick or Hoogsteen base pairing, has a smaller effect on the stability of triple helix. The order of stability is: no phosphate on either strand > phosphate on both pyrimidine strands > phosphate on purine strand > phosphate on all three strands. Differential stability of triple helix species is postulated to stem from an increase in rigidity due to steric hindrance from the 5'-phosphate. This result indicates that labelling with 32P affect equilibrium in triplex formation.     

Effect of 5-methylcytosine on the stability of triple-stranded DNA--a thermodynamic study.

We have previously shown that the pyrimidine oligonucleotide 5'CTTCCTCCTCT (Y11) recognizes the double-helical stem of hairpin 5'GAAGGAGGAGA-T4-TCTCCTCCTTC (h26) by triple-helix formation (1). In this paper, we report the effect on triplex formation of substituting the cytosine residues of Y11 with 5-methylcytosines (5meY11). In addition, we have studied the thermodynamics of the interaction between h26 and 5meY11. The results can be summarised as follows: (i) gel electrophoresis shows that at T = 5 degrees C and pH 5, both Y11 and 5meY11 form DNA triple helices with h26, whereas at pH 6.8 only the methylated strand binds to h26; (ii) pH-stability curves of the DNA triplexes formed from h26 + Y11 and h26 + 5meY11 show that Y11 and 5meY11 are semi-protonated at pH 5.7 and 6.7, respectively. Thus, it is concluded that cytosine methylation expands the pH range compatible with triplex formation by one pH unit; (iii) as the unmethylated triplex (h26:Y11), the methylated one (h26:5meY11) denatures in a biphasic manner, in which the low temperature transition results from the dissociation of 5meY11 from h26. The Tm of the triplex to h26 plus 5meY11 transition is strongly enhanced (about 10 degrees C) by cytosine methylation. A van 't Hoff analysis of denaturation curves is presented; (iv) DSC experiments show that triplex formation between 5meY11 and h26 is characterized by delta H = -237 +/- 25 kJ/mol and delta S = -758 +/- 75 J/Kmol, corresponding to an average delta H of -21 kJ/mol and delta S of -69 J/Kmol per Hoogsteen base pair; (v) the thermodynamic analysis indicates that the extra stability imparted to the triplex by methylcytosine is entropic in origin.     

Rational design of switched triple helix-forming oligonucleotides: Extension of sequences for triple helix formation

A rational design by means of molecular mechanics has been carried out in an effort to extend the range of double-helical DNA sequences that could be recognized by triple helix-forming oligonucleotides. The DNA target is composed of alternating, adjacent fragments of oligopurine·oligopyrimidine sequences, instead of a long stretch of polypurine·polypyrimidine sequence used for canonical triple helix formation. Based on the combination of different triple helix motifs in eitherHoogsteen orreverse Hoogsteen configuration, mini-triple helices can be formed at each oligopurine·oligopyrimidine part of the target sequence with either parallel or antiparallel orientation with respect to the purine strand. As the adjacent purine target sequences are located in the complementary strands, the third strand oligonucleotides can be joined together through a natural phosphodiester backbone at the junctions in either a 5-3 or a 3-5 polarity. There are six distinct junction steps. Molecular modeling was aimed at optimizing the cooperative binding of the so-called switched triple helix-forming oligonucleotides by choosing appropriate nucleotide(s) at the junction between two adjacent minitriple helices. A comprehensiveswitch code describing the rules for forming switched triple helices has been established. Its practical applications in extending DNA recognition by this new generation of tailor-made triple helix-forming oligonucleotides are discussed.     

Physico-chemical studies on DNA triplexes containing an alternate third strand with a non-nucleotide linker

Differential scanning calorimetric (DSC), circular dichroism (CD) and molecular mechanics studies have been performed on two triple helices of DNA. The target duplex consists of 16 base pairs in alternate sequence of the type 5′-(purine)_m(pyrimidine)_m-3′. In both the triplexes, the third oligopyrimidine strand crosses the major groove at the purine–pyrimidine junction, with a simultaneous binding of the adjacent purine tracts on alternate strands of the Watson–Crick duplex. The switch is ensured by a non-nucleotide linker, the 1,2,3 propanetriol residue, that joins two 3′–3′ phosphodiester ends. The third strands differ from each other for a nucleotide in the junction region. The resulting triple helices were termed 14-mer-PXP and 15-mer-PXP (where P=phosphate and X=1,2,3-propanetriol residue) according to the number of nucleotides that compose the third strand. DSC data show two independent processes: the first corresponding to the dissociation of the third strand from the target duplex, the second to the dissociation of the double helix in two single strands. The two triple helices show the same stability at pH 6.6. At pH 6.0, the 15-mer-PXP triplex is thermodynamically more stable than the 14-mer-PXP triplex. Thermodynamic data are discussed in relation to structural models. The results are useful when considering the design of oligonucleotides that can bind in an antigene approach to the DNA for therapeutic purposes.     

NMR studies of DNA (R+)n.(Y-)n.(Y+)n triple helices in solution: imino and amino proton markers of T.A.T and C.G.C+ base-triple formation

High-resolution exchangeable proton two-dimensional NMR spectra have been recorded on 11-mer DNA triple helices containing one oligopurine (R)n and two oligopyrimidine (Y)n strands at acidic pH and elevated temperatures. Our two-dimensional nuclear Overhauser effect studies have focused on an 11-mer triplex where the third oligopyrimidine strand is parallel to the oligopurine strand. The observed distance connectivities establish that the third oligopyrimidine strand resides in the major groove with the triplex stabilized through formation of T.A.T and C.G.C+ base triples. The T.A.T base triple can be monitored by imino protons of the thymidines involved in Watson-Crick (13.65-14.25 ppm) and Hoogsteen (12.9-13.55 ppm) pairing, as well as the amino protons of adenosine (7.4-7.7 ppm). The amino protons of the protonated (8.5-10.0 ppm) and unprotonated (6.5-8.3 ppm) cytidines in the C.G.C+ base triple provide distinct markers as do the imino protons of the guanosine (12.6-13.3 ppm) and the protonated cytidine (14.5-16.0 ppm). The upfield chemical shift of the adenosine H8 protons (7.1-7.3 ppm) establishes that the oligopurine strand adopts an A-helical base stacking conformation in the 11-mer triplex. These results demonstrate that oligonucleotide triple helices can be readily monitored by NMR at the individual base-triple level with distinct markers differentiating between Watson-Crick and Hoogsteen pairing. Excellent exchangeable proton spectra have also been recorded for (R+)n.(Y-)n.(Y+)n 7-mer triple helices with the shorter length permitting spectra to be recorded at ambient temperature.(ABSTRACT TRUNCATED AT 250 WORDS)     

Parallel-stranded DNA with Hoogsteen base pairing stabilized by a trans-[Pt(NH3)2]2+ cross-link: characterization and conversion into a homodimer and a triplex

The oligonucleotides 5'-d(TTTTCTTTTG) and 5'-d(AAAAGAAAAG) were cross-linked with a trans-[Pt(NH3)2]2+ entity via the N7 positions of the 3'-end guanine bases to give parallel-stranded (ps) DNA. At pH 4.2, CD and NMR spectroscopy indicate the presence of Hoogsteen base pairing. In addition, temperature-dependent UV spectroscopy shows an increase in melting temperature for the platinated duplex (35 degrees C) as compared to the non-platinated, antiparallel-stranded duplex formed from the same oligonucleotides (21 degrees C). A monomer-dimer equilibrium for the platinated 20mer is revealed by gel electrophoresis. At pH 4.2, addition of a third strand of composition 5'-d(AGCTTTTCTTTTAG) to the ps duplex leads to the formation of a triple helix with two distinct melting points at 38 degrees C (platinum cross-linked Hoogsteen part) and 21 degrees C (Watson-Crick part), respectively.     

Monitoring denaturation behaviour and comparative stability of DNA triple helices using oligonucleotide-gold nanoparticle conjugates

Gold nanoparticle labels, combined with UV-visible optical absorption spectroscopic methods, are employed to probe the temperature-dependent solution properties of DNA triple helices. By using oligonucleotide-nanoparticle conjugates to characterize triplex denaturation, for the first time triplex to duplex melting transitions may be sensitively monitored, with minimal signal interference from duplex to single strand melting, for both parallel and antiparallel triple helices. Further, the comparative sequence-dependent stability of DNA triple helices may also be examined using this approach. Specifically, triplex to duplex melting transitions for triplexes formed using oligonucleotides that incorporate 8-aminoguanine derivatives were successfully monitored and stabilization of both parallel and antiparallel triplexes following 8-aminoguanine substitutions is demonstrated.     

Monitoring denaturation behaviour and comparative stability of DNA triple helices using oligonucleotide–gold nanoparticle conjugates

Gold nanoparticle labels, combined with UV-visible optical absorption spectroscopic methods, are employed to probe the temperature-dependent solution properties of DNA triple helices. By using oligonucleotide–nanoparticle conjugates to characterize triplex denaturation, for the first time triplex to duplex melting transitions may be sensitively monitored, with minimal signal interference from duplex to single strand melting, for both parallel and antiparallel triple helices. Further, the comparative sequence-dependent stability of DNA triple helices may also be examined using this approach. Specifically, triplex to duplex melting transitions for triplexes formed using oligonucleotides that incorporate 8-aminoguanine derivatives were successfully monitored and stabilization of both parallel and antiparallel triplexes following 8-aminoguanine substitutions is demonstrated.     

Relative stabilities of triple helices composed of combinations of DNA, RNA and 2'-O-methyl-RNA backbones: chimeric circular oligonucleotides as probes.

Described is a systematic study of the effects of varied backbone structure on the stabilities of pyr.pur.pyr triple helices. The effects were measured using six circular 34 base oligonucleotides containing DNA (D), RNA (R) and/or 2'-O-methyl-RNA (M) residues designed to bind a complementary single-stranded purine target strand by triple helix formation. Eighteen different backbone combinations were studied at pH 5.5 and 7.0 by optical melting experiments and the results compared with the stabilities of the corresponding Watson-Crick duplexes. When the target purine strand is DNA, all circles form pH-dependent triple helical complexes which are considerably stronger than the duplexes alone. When RNA is the target, five of the nine complexes studied are of the pH-dependent triplex type and the other four complexes are not significantly stronger than the corresponding duplexes. The results are useful in the design of the highest affinity ligands for single- and double-stranded DNAs and RNAs and also point out novel ways to engender DNA- or RNA-selective binding.     

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.     

A directional nucleation-zipping mechanism for triple helix formation

A detailed kinetic study of triple helix formation was performed by surface plasmon resonance. Three systems were investigated involving 15mer pyrimidine oligonucleotides as third strands. Rate constants and activation energies were validated by comparison with thermodynamic values calculated from UV-melting analysis. Replacement of a T·A base pair by a C·G pair at either the 5′ or the 3′ end of the target sequence allowed us to assess mismatch effects and to delineate the mechanism of triple helix formation. Our data show that the association rate constant is governed by the sequence of base triplets on the 5′ side of the triplex (referred to as the 5′ side of the target oligopurine strand) and provides evidence that the reaction pathway for triple helix formation in the pyrimidine motif proceeds from the 5′ end to the 3′ end of the triplex according to the nucleation-zipping model. It seems that this is a general feature for all triple helices formation, probably due to the right-handedness of the DNA double helix that provides a stronger base stacking at the 5′ than at the 3′ duplex–triplex junction. Understanding the mechanism of triple helix formation is not only of fundamental interest, but may also help in designing better triple helix-forming oligonucleotides for gene targeting and control of gene expression.     

Exclusion of RNA strands from a purine motif triple helix.

Research concerning oligonucleotide-directed triple helix formation has mainly focused on the binding of DNA oligonucleotides to duplex DNA. The participation of RNA strands in triple helices is also of interest. For the pyrimidine motif (pyrimidine.purine.pyrimidine triplets), systematic substitution of RNA for DNA in one, two, or all three triplex strands has previously been reported. For the purine motif (purine.purine.pyrimidine triplets), studies have shown only that RNA cannot bind to duplex DNA. To extend this result, we created a DNA triple helix in the purine motif and systematically replaced one, two, or all three strands with RNA. In dramatic contrast to the general accommodation of RNA strands in the pyrimidine triple helix motif, a stable triplex forms in the purine motif only when all three of the substituent strands are DNA. The lack of triplex formation among any of the other seven possible strand combinations involving RNA suggests that: (i) duplex structures containing RNA cannot be targeted by DNA oligonucleotides in the purine motif; (ii) RNA strands cannot be employed to recognize duplex DNA in the purine motif; and (iii) RNA tertiary structures are likely to contain only isolated base triplets in the purine motif.     

Triple helix DNA oligomer melting measured by fluorescence polarization anisotropy

A synthetic DNA triple helix sequence was formed by annealing a pyrimidinic 21 mer single strand sequence onto the complementary purinic sequence centred on a 27 mer duplex DNA. Melting of the third strand was monitored by UV spectrophotometry in the temperature range 10-90 degrees C. The T(m) of the triplex, 37 degrees C, was well separated from the onset of duplex melting. When the same triple helix was formed on the duplex bearing one nick in the center of the pyrimidinic sequence the T(m) of the triplex was shifted to approximately 32 degrees C and overlapped the melting of the duplex. We have used fluorescence polarization anisotropy (FPA) measurements of ethidium bromide (EB) intercalated in duplex and triplex samples to determine the hydrodynamic parameters in the temperature range 10-40 degrees C. The fluorescence lifetime of EB in the samples of double and triple stranded DNA is the same (21.3 +/- 0.5 ns) at 20 degrees C, indicating that the geometries of the intercalation sites are similar. The values for the hydration radii of the duplex, normal triplex, and nicked triplex samples were 10.7 +/- 0.2, 12.2 +/- 0.2, and 12.0 +/- 0.2 A. FPA measurements on normal triplex DNA as a function of temperature gave a melting profile very similar to that derived by UV absorption spectroscopy. For the triplex carrying a nick, the melting curve obtained using FPA showed a clear shift compared with that obtained for the normal triplex sample. The torsional rigidity of the triplex forms was found to be higher than that of the duplex form.