Circular dichroism and UV melting studies on formation of an intramolecular triplex containing parallel T*A:T and G*G:C triplets: netropsin complexation with the triplex.

We have used circular dichroism and UV absorption spectroscopy to characterize the formation and melting behaviour of an intramolecular DNA triple helix containing parallel T*A:T and G*G:C triplets. Our approach to induce and to stabilize a parallel triplex involves the oligonucleotide 5'-d(G4A4G4[T4]C4T4C4-[T4]G4T4G4) ([T4] represents a stretch of four thymine residues). In a 10 mM sodium cacodylate, 0.2 mM disodium EDTA (pH 7) buffer, we have shown the following significant results. (i) While in the absence of MgCl2 this oligonucleotide adopts an intramolecular hairpin duplex structure prolonged by the single strand extremity 5'-d([T4]G4T4G4), the presence of millimolar concentrations of MgCl2generates an intramolecular triplex (via double hairpin formation). (ii) In contrast to the antiparallel triplex formed by the oligonucleotide 5'-d(G4T4G4[T4]G4A4G4[T4]C4T4C4), the parallel triplex melts in a biphasic manner (a triplex to duplex transition followed by a duplex to coil transition) and is less stable than the antiparallel one. The enthalpy change associated with triplex formation (-37 kcal/mol) is approximately half that of duplex formation (-81 kcal/mol). (iii) The parallel triple helix is disrupted by increasing the concentration of KCl(>10 mM), whereas, under the same conditions, the antiparallel triplex remains stable. (iv) Netropsin, a natural DNA minor groove-binding ligand, binds to the central site A4/T4of the duplex or triplex in an equimolar stoichiometry. Its association constant K is smaller for the parallel triplex ( approximately 1 x 10(7) M-1) than for the antiparallel one ( approximately 1 x 10(8) M-1). In contrast to the antiparallel structure, netropsin binding has no apparent effect on thermal stability of the parallel triple helix.     

Alternate strand recognition of double-helical DNA by (T,G)-containing oligonucleotides in the presence of a triple helix-specific ligand.

Triple helix formation requires a polypurine- polypyrimidine sequence in the target DNA. Recent works have shown that this constraint can be circumvented by using alternate strand triplex-forming oligonucleotides. We have previously demonstrated that (T,G)-containing triplex- forming oligonucleotides may adopt a parallel or an antiparallel orientation with respect to an oligopurine target, depending upon the sequence and, in particular, upon the number of 5'-GpT-3' and 5'-TpG-3' steps [Sun et al. (1991) C.R. Acad. Sci. Paris Ser III, 313, 585-590]. A single (T,G)-containing oligonucleotide can therefore interact with two oligopurine stretches which alternate on the two strands of the target DNA. The (T,G) switch oligonucleotide contains a 5'-part targeted to one of the oligopurine sequences in a parallel orientation followed by a 3'-part that adopts an antiparallel orientation with respect to the second oligopurine sequence. We show that a limitation to the stability of such a triplex may arise from the instability of the antiparallel part, composed of reverse-Hoogsteen C.GxG and T.AxT base triplets. Using DNase I footprinting and ultraviolet absorption experiments, we report that a benzo[e]pyridoindole derivative [(3-methoxy- 7H-8-methyl-11-[(3'-amino-propyl) amino] benzo[e]pyrido [4,3-b]indole (BePI)], a drug interacting more tightly with a triplex than with a duplex DNA, strongly stabilizes triplexes with reverse-Hoogsteen C.GxG and T.AxT triplets thus allowing a stabilization of the triplex-forming switch (T,G) oligonucleotide on alternating oligopurine- oligopyrimidine 5'-(Pu)14(Py)14-3' duplex sequences. These results lead to an extension of the range of oligonucleotide sequences for alternate strand recognition of duplex DNA.     

Binding of netropsin to a DNA triple helix.

The interaction of netropsin, a minor groove binding drug, with T-A-T triple helix and A-T double helix was studied using circular dichroism spectroscopy and thermal denaturation. The triple helix was made by an oligonucleotide (dA)12-x-(dT)12-x-(dT)12, where x is a hexaethylene glycol chain bridged between the 3' phosphate of one strand and the 5' phosphate of the following strand. This oligonucleotide is able to fold back on itself to form a very stable triplex. Changing the conditions allows the same oligonucleotide in a duplex form with a (dT)12 dangling arm. Circular dichroism spectroscopy demonstrates that netropsin can bind to the triple helical structure. Spectral analysis shows that the bound drug exhibits a conformation and an environment similar in double-stranded and in triple-stranded structure. However, the binding constant to the triple-stranded structure is found smaller than the binding constant to the double-stranded one. Thermal denaturation experiments demonstrate that netropsin destabilizes the triplex whereas it stabilizes the duplex.     

Protein-free parallel triple-stranded DNA complex formation

A 14 nt DNA sequence 5′-AGAATGTGGCAAAG-3′ from the zinc finger repeat of the human KRAB zinc finger protein gene ZNF91 bearing the intercalator 2-methoxy,6-chloro,9-amino acridine (Acr) attached to the sugar–phosphate backbone in various positions has been shown to form a specific triple helix (triplex) with a 16 bp hairpin (intramolecular) or a two-stranded (intermolecular) duplex having the identical sequence in the same (parallel) orientation. Intramolecular targets with the identical sequence in the antiparallel orientation and a non-specific target sequence were tested as controls. Apparent binding constants for formation of the triplex were determined by quantitating electrophoretic band shifts. Binding of the single-stranded oligonucleotide probe sequence to the target led to an increase in the fluorescence anisotropy of acridine. The parallel orientation of the two identical sequence segments was confirmed by measurement of fluorescence resonance energy transfer between the acridine on the 5′-end of the probe strand as donor and BODIPY-Texas Red on the 3′-amino group of either strand of the target duplex as acceptor. There was full protection from OsO₄-bipyridine modification of thymines in the probe strand of the triplex, in accordance with the presumed triplex formation, which excluded displacement of the homologous duplex strand by the probe–intercalator conjugate. The implications of these results for the existence of protein-independent parallel triplexes are discussed.     

Thermodynamic and computational studies of DNA triple helices containing a nucleotide or a non-nucleotide linker in the third strand.

In this paper we report a thermodynamic characterisation of stability and melting behaviour of four different triple helices at pH 6.0. The target duplex consists of 16 base pairs in alternate sequence of the type 5'-(purine)(m)(pyrimidine)(m)-3'. The four triplexes are formed by targeting the 16-mer duplex with an all pyrimidine 16-mer or 15-mer or 14-mer third strand. The 16-mer oligonucleotide contains a 3'-3' phosphodiester junction and corresponding triplex was named 16-mer P. The 14-mer oligonucleotide contains a non-nucleotide linker, the 1,2,3 propanetriol residue and the corresponding triplex was named 14-mer PT. For the 15-mer oligonucleotide both junctions were alternatively used and the relative triplexes were named 15-mer P and 15-mer PT, respectively. These linkers introduce the appropriate polarity inversion and let the third strand switch from one oligopurine strand of the duplex to the other. Thermal denaturation profiles indicate the initial loss of the third strand followed by the dissociation of the target duplex. Transition enthalpies, entropies and free energies were derived from differential scanning calorimetric measurements. The comparison of Gibbs energies reveals that a more stable triplex is obtained when in the third strand there is the lack of one nucleotide in the junction region and a propanetriol residue as linker was used. The thermodynamic data were discussed in light of molecular mechanics and dynamics calculations.     

Presence of divalent cation is not mandatory for the formation of intramolecular purine-motif triplex containing human c-jun protooncogene target

Modulation of endogenous gene function, through sequence-specific recognition of double helical DNA via oligonucleotide-directed triplex formation, is a promising approach. Compared to the formation of pyrimidine motif triplexes, which require relatively low pH, purine motif appears to be the most gifted for their stability under physiological conditions. Our previous work has demonstrated formation of magnesium-ion dependent highly stable intermolecular triplexes using a purine third strand of varied lengths, at the purine?pyrimidine (Pu?Py) targets of SIV/HIV-2 (vpx) genes (Svinarchuk, F., Monnot, M., Merle, A., Malvy, C., and Fermandjian, S. (1995) Nucleic Acids Res. 23, 3831-3836). Herein, we show that a designed intramolecular version of the 11-bp core sequence of the said targets, which also constitutes an integral, short, and symmetrical segment (G(2)AG(5)AG(2))?(C(2)TC(5)TC(2)) of human c-jun protooncogene forms a stable triplex, even in the absence of magnesium. The sequence d-C(2)TC(5)TC(2)T(5)G(2)AG(5)AG(2)T(5)G(2)AG(5)AG(2) (I-Pu) folds back twice onto itself to form an intramolecular triple helix via a double hairpin formation. The design ensures that the orientation of the intact third strand is antiparallel with respect to the oligopurine strand of the duplex. The triple helix formation has been revealed by non-denaturating gel assays, UV-thermal denaturation, and circular dichroism (CD) spectroscopy. The monophasic melting curve, recorded in the presence of sodium, represented the dissociation of intramolecular triplex to single strand in one step; however, the addition of magnesium bestowed thermal stability to the triplex. Formation of intramolecular triple helix at neutral pH in sodium, with or without magnesium cations, was also confirmed by gel electrophoresis. The triplex, mediated by sodium alone, destabilizes in the presence of 5'-C(2)TC(5)TC(2)-3', an oligonucleotide complementary to the 3'-oligopurine segments of I-Pu, whereas in the presence of magnesium the triplex remained impervious. CD spectra showed the signatures of triplex structure with A-like DNA conformation. We suggest that the possible formation of pH and magnesium-independent purine-motif triplexes at genomic Pu?Py sequences may be pertinent to gene regulation.     

Stabilization of DNA double and triple helices by conjugation of minor groove binders to oligonucleotides

New conjugates containing two parallel or antiparallel carboxamide minor groove binders (MGB) attached to the same terminal phosphate of one oligonucleotide strand were synthesized. The conjugates interact with their target DNA stronger than the individual components. Effect of conjugated MGB on DNA duplex and triplex stability and their sequence specificity was demonstrated on the short oligonucleotide duplexes and on the triplex formed by model 16-mer oligonucleotide with HIV polypurine tract.     

Triple helix formation with purine-rich phosphorothioate-containing oligonucleotides covalently linked to an acridine derivative.

Purine-rich (GA)- and (GT)-containing oligophosphorothioates were investigated for their triplex-forming potential on a 23 bp DNA duplex target. In our system, GA-containing oligophosphorothioates (23mer GA-PS) were capable of triplex formation with binding affinities lower than (GA)-containing oligophosphodiesters (23mer GA-PO). The orientation of the third strand 23mers GA-PS and GA-PO was antiparallel to the purine strand of the duplex DNA target. In contrast, (GT)-containing oligophosphorothioates (23mer GT-PS) did not support triplex formation in either orientation, whereas the 23mer GT-PO oligophosphodiester demonstrated triplex formation in the antiparallel orientation. GA-PS oligonucleotides, in contrast to GT-PS oligonucleotides, were capable of self-association, but these self-associated structures exhibited lower stabilities than those formed with GA-PO oligonucleotides, suggesting that homoduplex formation (previously described for the 23mer GA-PO sequence by Noonberg et al.) could not fully account for the decrease in triplex stability when phosphorothioate linkages were used. The 23mer GA-PS oligonucleotide was covalently linked via its 5'-end to an acridine derivative (23mer Acr-GA-PS). In the presence of potassium cations, this conjugate demonstrated triplex formation with higher binding affinity than the unmodified 23mer GA-PS oligonucleotide and even than the 23mer GA-PO oligonucleotide. A (GA)-containing oligophosphodiester with two phosphorothioate linkages at both the 5'- and 3'-ends exhibited similar binding affinity to duplex DNA compared with the unmodified GA-PO oligophosphodiester. This capped oligonucleotide was more resistant to nucleases than the GA-PO oligomer and thus represents a good alternative for ex vivo applications of (GA)-containing, triplex-forming oligonucleotides, allowing a higher binding affinity for its duplex target without rapid cellular degradation.     

Unwinding of a DNA triple helix by the Werner and Bloom syndrome helicases

Bloom syndrome and Werner syndrome are genome instability disorders, which result from mutations in two different genes encoding helicases. Both enzymes are members of the RecQ family of helicases, have a 3' --> 5' polarity, and require a 3' single strand tail. In addition to their activity in unwinding duplex substrates, recent studies show that the two enzymes are able to unwind G2 and G4 tetraplexes, prompting speculation that failure to resolve these structures in Bloom syndrome and Werner syndrome cells may contribute to genome instability. The triple helix is another alternate DNA structure that can be formed by sequences that are widely distributed throughout the human genome. Here we show that purified Bloom and Werner helicases can unwind a DNA triple helix. The reactions are dependent on nucleoside triphosphate hydrolysis and require a free 3' tail attached to the third strand. The two enzymes unwound triplexes without requirement for a duplex extension that would form a fork at the junction of the tail and the triplex. In contrast, a duplex formed by the third strand and a complement to the triplex region was a poor substrate for both enzymes. However, the same duplex was readily unwound when a noncomplementary 5' tail was added to form a forked structure. It seems likely that structural features of the triplex mimic those of a fork and thus support efficient unwinding by the two helicases.     

Design and simple routes of synthesis of oligonucleotide conjugates for studies of DNA triple helix formation

A series of oligonucleotides conjugated to intercalators, as well as fluorescent and lipophilic substances, minor groove binders and photoactive molecules were synthesized for studies of their ability to form a stable triple helix. Purine-rich short double stranded DNA fragments from HIV-1 genome and pyrimidine 16-mer oligodeoxyribonucleotide were used as models. A conjugate of a dipyrido[3,2-a:2',3'-c]phenazine-ruthenium (II) complex and a triple helix-forming oligonucleotide was constructed. Upon sequence-specific duplex and triplex formation of the conjugate, the ruthenium complex becomes highly fluorescent. The attached ruthenium complex induces a stabilization of the DNA triple helix and a significant increase of the time of residence of the third strand on the duplex.     

Stabilization of DNA Double and Triple Helices by Conjugation of Minor Groove Binders to Oligonucleotides

Abstract

New conjugates containing two parallel or antiparallel carboxamide minor groove binders (MGB) attached to the same terminal phosphate of one oligonucleotide strand were synthesized. The conjugates interact with their target DNA stronger than the individual components. Effect of conjugated MGB on DNA duplex and triplex stability and their sequence specificity was demonstrated on the short oligonucleotide duplexes and on the triplex formed by model 16-mer oligonucleotide with HIV polypurine tract.     

Targeting pyrimidine single strands by triplex formation: structural optimization of binding.

Recent reports describe a new strategy for the binding of single-stranded pyrimidine sequences by triple helix formation. In this approach, a double-length purine-rich oligonucleotide binds a target strand, folding back to form an antiparallel pur.pur.pyr triple helix. We now describe a series of studies in which sequence and structural variations are made in such purine-rich ligands, in an effort to optimize binding properties. Comparison is made between the use of two separate strands and the use of single two-domain ligands; the latter are found to bind more tightly and to aggregate less in media containing Na+ or K+. Placement of mismatched bases in the target shows that sequence selectivity of binding is as high as that for Watson-Crick duplex formation. Variation of the lengths and sequences of loops bridging the binding domains demonstrates that dinucleotide loops composed of pyrimidines give the highest stability. Oligoethylene glycol-derived loop replacements are shown to give good binding affinity as well. The binding of an RNA target is shown to occur with the same affinity as the binding of DNA. In general, it is found that circular variants bind more tightly than do either separate strands or singly-linked ligands and unlike linear oligomers, the circular compounds do not aggregate to a large extent even in buffers containing 100 mM K+. Such structurally optimized ligands are useful in expanding the number of possible naturally-occurring sequences which can be targeted by triplex formation.     

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.     

Repairing the sickle cell mutation. I. Specific covalent binding of a photoreactive third strand to the mutated base pair.

A DNA third strand with a 3'-psoralen substituent was designed to form a triplex with the sequence downstream of the T.A mutant base pair of the human sickle cell beta-globin gene. Triplex-mediated psoralen modification of the mutant T residue was sought as an approach to gene repair. The 24-nucleotide purine-rich target sequence switches from one strand to the other and has four pyrimidine interruptions. Therefore, a third strand sequence favorable to two triplex motifs was used, one parallel and the other antiparallel to it. To cope with the pyrimidine interruptions, which weaken third strand binding, 5-methylcytosine and 5-propynyluracil were used in the third strand. Further, a six residue "hook" complementary to an overhang of a linear duplex target was added to the 5'-end of the third strand via a T(4) linker. In binding to the overhang by Watson-Crick pairing, the hook facilitates triplex formation. This third strand also binds specifically to the target within a supercoiled plasmid. The psoralen moiety at the 3'-end of the third strand forms photoadducts to the targeted T with high efficiency. Such monoadducts are known to preferentially trigger reversion of the mutation by DNA repair enzymes.     

DESIGN AND SIMPLE ROUTES OF SYNTHESIS OF OLIGONUCLEOTIDE CONJUGATES FOR STUDIES OF DNA TRIPLE HELIX FORMATION

A series of oligonucleotides conjugated to intercalators, as well as fluorescent and lipophilic substances, minor groove binders and photoactive molecules were synthesized for studies of their ability to form a stable triple helix. Purine-rich short double stranded DNA fragments from HIV-1 genome and pyrimidine 16-mer oligodeoxyribonucleotide were used as models. A conjugate of a dipyrido[3,2-a:2′,3′-c]phenazine-ruthenium (II) complex and a triple helix-forming oligonucleotide was constructed. Upon sequence-specific duplex and triplex formation of the conjugate, the ruthenium complex becomes highly fluorescent. The attached ruthenium complex induces a stabilization of the DNA triple helix and a significant increase of the time of residence of the third strand on the duplex.     

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.     

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.     

Extension of the range of DNA sequences available for triple helix formation: stabilization of mismatched triplexes by acridine-containing oligonucleotides.

Triple helix formation usually requires an oligopyrimidine*oligopurine sequence in the target DNA. A triple helix is destabilized when the oligopyrimidine*oligopurine target contains one (or two) purine*pyrimidine base pair inversion(s). Such an imperfect target sequence can be recognized by a third strand oligonucleotide containing an internally incorporated acridine intercalator facing the inverted purine*pyrimidine base pair(s). The loss of triplex stability due to the mismatch is partially overcome. The stability of triplexes formed at perfect and imperfect target sequences was investigated by UV thermal denaturation experiments. The stabilization provided by an internally incorporated acridine third strand oligonucleotide depends on the sequences flanking the inverted base pair. For triplexes containing a single mismatch the highest stabilization is observed for an acridine or a propanediol tethered to an acridine on its 3'-side facing an inverted A*T base pair and for a cytosine with an acridine incorporated to its 3'-side or a guanine with an acridine at its 5'-side facing an inverted G*C base pair. Fluorescence studies provided evidence that the acridine was intercalated into the triplex. The target sequences containing a double base pair inversion which form very unstable triplexes can still be recognized by oligonucleotides provided they contain an appropriately incorporated acridine facing the double mismatch sites. Selectivity for an A*T base pair inversion was observed with an oligonucleotide containing an acridine incorporated at the mismatched site when this site is flanked by two T*A*T base triplets. These results show that the range of DNA base sequences available for triplex formation can be extended by using oligonucleotide intercalator conjugates.