Stabilization of triple helical DNA by a benzopyridoquinoxaline intercalator

High-throughput screening of triplex DNA binders from complicated samples by 96-well pate format in conjunction with peak area-fading UHPLC-Orbitrap MS

Screening triplex DNA binders from complicated samples in a high-throughput fashion with good reproducibility without the requirement of an extra releasing step.

Exploring multiple binding sites of an indoloquinoline in triple-helical DNA: a paradigm for DNA triplex-selective intercalators

Employing NMR spectroscopic methods preferred binding sites of a triplex-selective indoloquinoline drug were examined with three DNA triplex targets. To directly derive and evaluate number and type of the different sites of interaction, studies were performed on short triple-helical constructs specifically labeled with 3-(15)N thymidine probes. The detection and assignment of several coexisting species was enabled through the observation of slow exchange on the chemical shift timescale between complexes and free triplex. In general, the 5'-triplex-duplex junction constitutes the most favorable intercalation site, in particular when flanked by a TAT base triad. NMR data also revealed two different orientations for the intercalating indoloquinoline drug. Binding affinity significantly decreases with a C(+)GC triad bordering the junction but junction binding is still preferred over intercalation between TAT base triads within the triplex stem. In addition to the intercalation between two uncharged TAT triplets, intercalation between a TAT and a 3'-terminal C(+)GC triplet was also observed, indicating a non-protonated third strand cytosine at the triplex end position.

Potent triple helix stabilization by 5',3'-modified triplex-forming oligonucleotides

Anthraquinone and pyrene analogues attached to the 3' and/or 5' termini of triplex-forming oligonucleotides (TFOs) by various linkers increased the stability of parallel triple helices. The modifications are simple to synthesize and can be introduced during standard solid-phase oligonucleotide synthesis. Potent triplex stability was achieved by using doubly modified TFOs, which in the most favourable cases gave an increase in melting temperature of 30 degrees C over the unmodified counterparts and maintained their selectivity for the correct target duplex. Such TFOs can produce triplexes with melting temperatures of 40 degrees C at pH 7 even though they do not contain any triplex-stabilizing base analogues. These studies have implications for the design of triplex-forming oligonucleotides for use in biology and nanotechnology.

Discovery of novel triple helical DNA intercalators by an integrated virtual and actual screening platform

Virtual Screening is an increasingly attractive way to discover new small molecules with potential medicinal value. We introduce a novel strategy that integrates use of the molecular docking software Surflex with experimental validation by the method of competition dialysis. This integrated approach was used to identify ligands that selectively bind to the triplex DNA poly(dA)-[poly(dT)]₂. A library containing ∼2 million ligands was virtually screened to identify compounds with chemical and structural similarity to a known triplex intercalator, the napthylquinoline MHQ-12. Further molecular docking studies using compounds with high structural similarity resulted in two compounds that were then demonstrated by competition dialysis to have a superior affinity and selectivity for the triplex nucleic acid than MHQ-12. One of the compounds has a different chemical backbone than MHQ-12, which demonstrates the ability of this strategy to ‘scaffold hop’ and to identify small molecules with novel binding properties. Biophysical characterization of these compounds by circular dichroism and thermal denaturation studies confirmed their binding mode and selectivity. These studies provide a proof-of-principle for our integrated screening strategy, and suggest that this platform may be extended to discover new compounds that target therapeutically relevant nucleic acid morphologies.

Spectroscopic studies on the formation and thermal stability of DNA triplexes with a benzoannulated delta-carboline-oligonucleotide conjugate

A benzoannulated delta-carboline with a phenyl substituent has been covalently tethered to the 3'-end of a triplex-forming oligonucleotide and its ability to bind and stabilize DNA triple helices has been examined by various spectroscopic methods. UV thermal melting experiments were conducted with different hairpin duplexes and with a complementary single-stranded oligonucleotide as targets for the conjugate. The delta-carboline ligand preferentially binds triplexes over duplexes and leads to a temperature increase of the triplex-to-duplex transition by up to 23 degrees C. The results obtained from UV, CD and fluorescence measurements suggest that the delta-carboline ligand exhibits specific interactions with a triplex and favors binding by intercalation at the triplex-duplex junction.

Ligand binding mode to duplex and triplex DNA assessed by combining electrospray tandem mass spectrometry and molecular modeling

In this paper, we report the analysis of seven benzopyridoindole and benzopyridoquinoxaline drugs binding to different duplex DNA and triple helical DNA, using an approach combining electrospray ionization mass spectrometry (ESI-MS), tandem mass spectrometry (MS/MS), and molecular modeling. The ligands were ranked according to the collision energy (CE(50)) necessary to dissociate 50% of the complex with the duplex or the triplex in tandem MS. To determine the probable ligand binding site and binding mode, molecular modeling was used to calculate relative ligand binding energies in different binding sites and binding modes. For duplex DNA binding, the ligand-DNA interaction energies are roughly correlated with the experimental CE(50), with the two benzopyridoindole ligands more tightly bound than the benzopyridoquinoxaline ligands. There is, however, no marked AT versus GC base preference in binding, as supported both by the ESI-MS and the calculated ligand binding energies. Product ion spectra of the complexes with triplex DNA show only loss of neutral ligand for the benzopyridoquinoxalines, and loss of the third strand for the benzopyridoindoles, the ligand remaining on the duplex part. This indicates a higher binding energy of the benzopyridoindoles, and also shows that the ligands interact with the triplex via the duplex. The ranking of the ligand interaction energies compared with the CE(50) values obtained by MS/MS on the complexes with the triplex clearly indicates that the ligands intercalate via the minor groove of the Watson-Crick duplex. Regarding triplex versus duplex selectivity, our experiments have demonstrated that the most selective drugs for triplex share the same heteroaromatic core.

A gold nanoparticle based approach for screening triplex DNA binders

Nanoparticle assemblies interconnected with DNA triple helixes can be used to colorimetrically screen for triplex DNA binding molecules and simultaneously determine their relative binding affinities based on melting temperatures. Nanoparticles assemble only when DNA triple helixes form between DNA from two different particles and a third strand of free DNA. In addition, the triple helix structure is unstable at room temperature and only forms in the presence of triplex DNA binding molecules which stabilize the triple helix. The resulting melting transition of the nanoparticle assembly is much sharper and at a significantly higher Tm than the analogous triplex structure without nanoparticles. Upon nanoparticle assembly, a concomitant red-to-blue color change occurs. The assembly process and color change do not occur in the presence of duplex DNA binders and therefore provide a significantly better screening process for triplex DNA binding molecules compared to standard methods.

Stable and selective formation of hoogsteen-type triplexes and duplexes using twisted intercalating nucleic acids (TINA) prepared via postsynthetic Sonogashira solid-phase coupling reactions

Bulge insertions of (R)-1-O-[4-(1-pyrenylethynyl)phenylmethyl]glycerol (5) into the middle of homopyrimidine oligodeoxynucleotides (twisted intercalating nucleic acids, TINA) obtained via postsynthetic Sonogashira coupling reaction led to extraordinary high thermal stability of Hoogsteen-type triplexes and duplexes, whereas Watson-Crick-type duplexes of the same nucleotide content were destabilized. Modified oligonucleotides were synthesized using the phosphoramidite of (S)-1-(4,4'-dimethoxytriphenylmethyloxy)-3-(4-iodo-benzyloxy)-propan-2-ol followed by treatment of the oligonucleotide on a CPG-support with the Sonogashira-coupling reaction mixture containing different ethynylaryls. Bulged insertion of the pyrene derivative 5 into oligonucleotides was found to be the best among the tested modifications for binding to the Hoogsteen-type triplexes and duplexes. Thus, at pH 7.2 an oligonucleotide with cytidine content of 36% possessing two bulged insertions of 5 separated by three bases formed a stable triplex (T(m) = 43.0 degrees C), whereas the native oligonucleotide was unable to bind to the target duplex. The corresponding Watson-Crick-type duplex with the same oligonucleotide had T(m) of 38.0 degrees C at pH 7.2, while the T(m) of unmodified dsDNA was 47.0 degrees C. Experiments with mismatched oligonucleotides, luminescent properties, and potential applications of TINA technology is discussed.

Triple-helix directed cleavage of double-stranded DNA by benzoquinoquinoxaline-1,10-phenanthroline conjugates

Oligonucleotide-directed triple-helix formation provides a rational means to interfere with genomic DNA targets and to direct modifications at specific sites. We have developed a new class of compounds that, at low concentrations, efficiently targets and damages double-stranded DNA specifically at the site where a triple-helical structure is formed. In these new compounds, a triple-helix-specific intercalator-benzoquinoquinoxaline (BQQ)-was coupled to one of two isomeric 1,10-phenanthrolinecarboxaldehyde derivatives. 1,10-Phenanthroline derivatives are known to cleave DNA in the presence of copper ions. The obtained BQQ-1,10-phenanthroline (BQQ-OP) conjugates were compared with regard to their ability to cleave triple-helix DNA. Both conjugates displayed a sequence preference inside the triple-helical site, as judged from the more pronounced cleavage obtained at stretches of TAxT base triplets.

Intercalating nucleic acids: the influence of linker length and intercalator type on their duplex stabilities

Six new examples of intercalating nucleic acids were synthesized in order to evaluate the dependence of the length of the linker between oligo and intercalator on the thermal stability of their corresponding duplexes and triplexes.

DNA sequence specificity of triplex-binding ligands

We have examined the ability of naphthylquinoline, a 2,7-disubstituted anthraquinone and BePI, a benzo[e]pyridoindole derivative, to stabilize parallel DNA triplexes of different base composition. Fluorescence melting studies, with both inter- and intramolecular triplexes, show that all three ligands stabilize triplexes that contain blocks of TAT triplets. Naphthylquinoline has no effect on triplexes formed with third strands composed of (TC)n or (CCT)n, but stabilizes triplexes that contain (TTC)n. In contrast, BePI slightly destabilizes the triplexes that are formed at (TC)n (CCT)n and (TTC)n. 2,7-Anthraquinone stabilizes (TC)n (CCT)n and (TTC)n, although it has the greatest effect on the latter. DNase I footprinting studies confirm that triplexes formed with (CCT)n are stabilized by the 2,7-disubstituted amidoanthraquinone but not by naphthylquinoline. Both ligands stabilize the triplex formed with (CCTT)n and neither affects the complex with (CT)n. We suggest that BePI and naphthylquinoline can only bind between adjacent TAT triplets, while the anthraquinone has a broader sequence of selectivity. These differences may be attributed to the presence (naphthylquinoline and BePI) or absence (anthraquinone) of a positive charge on the aromatic portion of the ligand, which prevents intercalation adjacent to C+GC triplets. The most stable structures are formed when the stacked rings (bases or ligand) alternate between charged and uncharged species. Triplexes containing alternating C+GC and TAT triplets are not stabilized by ligands as they would interrupt the alternating pattern of charged and uncharged residues.

Optimization of triple-helix-directed DNA cleavage by benzoquinoquinoxaline-ethylenediaminetetraacetic acid conjugates

The formation of triple-helical structures of DNA is based on sequence-specific recognition of oligopyrimidine.oligopurine stretches of double-helical DNA. Triple-helical structures can be stabilized by DNA-binding ligands. Benzoquinoquinoxaline (BQQ) derivatives are among the most potent intercalating-type agents known to stabilize DNA triple-helical structures. We previously reported the conversion of BQQ into a triplex-directed DNA cleaving agent, namely BQQ-ethylenediaminetetraacetic acid (EDTA), by coupling of 6-(3-aminopropylamino)BQQ to a suitable ethylenediaminetetraacetic acid derivative, and we demonstrated the ability of this conjugate to cause double-stranded cleavage of DNA at the triplex site. However, this prototype derivative BQQ-EDTA conjugate showed lower affinity towards triplex DNA than BQQ itself. In the light of this observation, and guided by molecular modeling studies, we synthesized a second generation of BQQ-EDTA conjugates based on 6-[bis(2-aminoethyl)amino]- and 6-(3,3'-diamino-N-methyldipropylamino)-BQQ derivatives. We confirmed by DNA melting experiments that the new conjugates displayed an increased specific affinity towards triple helices when compared to the previously synthesized BQQ-EDTA. In addition, the efficiency of these new agents in triplex-specific binding and cleavage was demonstrated by triplex-directed double-stranded cleavage of plasmid DNA.

Spectroscopic and thermodynamic studies on the binding of sanguinarine and berberine to triple and double helical DNA and RNA structures

A comparative study on the interaction of sanguinarine and berberine with DNA and RNA triplexes and their parent duplexes was performed, by using a combination of spectrophotometric, UV thermal melting, circular dichroic and thermodynamic techniques. Formation of the DNA and RNA triplexes was confirmed from UV-melting and circular dichroic measurements. The interaction process was characterized by increase of thermal melting temperature, perturbation in circular dichroic spectrum and the typical hypochromic and bathochromic effects in the absorption spectrum. Scatchard analysis indicated that both the alkaloids bound to the triplex and duplex structures in a non-cooperative manner and the binding was stronger to triplexes than to parent duplexes. Thermal melting studies further indicated that sanguinarine stabilized the Hoogsteen base paired third strand of both DNA and RNA triplexes more tightly compared to their Watson-Crick strands, while berberine stabilized the third strand only without affecting the Watson-Crick strand. However, sanguinarine stabilized the parent duplexes while no stabilization was observed with berberine under identical conditions. Circular dichroic studies were also consistent with the observation that perturbations of DNA and RNA triplexes were more compared to their parent duplexes in presence of the alkaloids. Thermodynamic data revealed that binding of sanguinarine and berberine to triplexes (T.AxT and U.AxU) and duplexes (A.T and A.U) showed negative enthalpy changes and positive entropy changes but that of sanguinarine to C.GxC(+) triplex and G.C duplex exhibited negative enthalpy and negative entropy changes. Taken together, these results suggest that both sanguinarine and berberine can bind and stabilize the DNA and RNA triplexes more strongly than their respective parent duplexes.

Bis-4-aminoquinolines: novel triple-helix DNA intercalators and antagonists of immunostimulatory CpG-oligodeoxynucleotides

Six dimeric 2-(2-naphthyl)quinolin-4-amines with a linker between the amino groups and eight dimeric 2-(4-anilino)quinolin-4-amines linked between the anilino groups were synthesized and evaluated for their interaction with duplex/triplex DNA's and as antagonists of immunostimulatory oligodeoxynucleotides with a CpG-motif (CpG-ODN). The most powerful triple-helix DNA intercalator known to date, with high affinity toward T.A.T triplets and triplex/duplex selectivity, was found. The potent antagonism of immunostimulatory CpG-ODN by several bis-4-aminoquinolines is not related to their DNA interactions.

Effect of divalent cations and cytosine protonation on thermodynamic properties of intermolecular DNA double and triple helices

The contribution of divalent cations and cytosine protonation to conformation and stability of duplex and triplex formation were intensively investigated and characterized by ultraviolet (UV), circular dichroism (CD), differential scanning calorimetry (DSC), and electrophoresis mobility shift assay (EMSA). CD spectra showed that the divalent cations investigated would not significantly distort nucleotide geometry, while UV and DSC melting experiments revealed that the cation binding abilities to duplexes and triplexes were clearly dependent on the types of cations under near physiological conditions. The calorimetric enthalpies were generally underestimated relative to the corresponding van't Hoff enthalpies for Hoogsteen and Watson-Crick transitions, but free energy changes derived from the DSC measurements were in good agreement with those derived from the UV measurements. The adjacent placing of the C(+) x G.C triplets in triplexes lowered the stabilities of not only Hoogsteen base-pairing but also Watson-Crick base-pairing. The protonation contribution of the given cytosine residues might depend on the local and global structure of the protonated cytosine complex. A rigid structural targeted-strand would favor the protonation of cytosine residues. The apparent pK(a) values for parallel duplex and triplex investigated were determined to be 6.4 and 7.6, respectively, which are considerably heightened by 2.1 and 3.3 pH unit as compared to the intrinsic pK(a) value of the free cytosine residues.

Design and optimization of camptothecin conjugates of triple helix-forming oligonucleotides for sequence-specific DNA cleavage by topoisomerase I

To achieve a sequence-specific DNA cleavage by topoisomerase I, derivatives of the antitumor drug camptothecin have been covalently linked to triple helix-forming oligonucleotides that bind in a sequence-specific manner to the major groove of double-helical DNA. Triplex formation at the target sequence positions the drug selectively at the triplex site, thereby stimulating topoisomerase I-mediated DNA cleavage at this site. In a continuous effort to optimize this strategy, a broad set of conjugates consisting of (i) 16-20-base-long oligonucleotides, (ii) alkyl linkers of variable length, and (iii) camptothecin derivatives substituted on the A or B quinoline ring were designed and synthesized. Analysis of the cleavage sites at nucleotide resolution reveals that the specificity and efficacy of cleavage depends markedly on the length of both the triple-helical structure and the linker between the oligonucleotide and the poison. The optimized hybrid molecules induced strong and highly specific cleavage at a site adjacent to the triplex. Furthermore, the drug-stabilized DNA-topoisomerase I cleavage complexes were shown to be more resistant to salt-induced reversal than the complexes induced by camptothecin alone. Such rationally designed camptothecin conjugates could provide useful antitumor drugs directed selectively against genes bearing the targeted triplex binding site. In addition, they represent a powerful tool to probe the molecular interactions in the DNA-topoisomerase I complex.

Stabilisation of TG- and AG-containing antiparallel DNA triplexes by triplex-binding ligands

We have used DNase I footprinting to examine the interaction of several triplex-binding ligands with antiparallel TG- and AG-containing triplexes. We find that although a 17mer TG-containing oligonucleotide on its own fails to produce a footprint at concentrations as high as 30 microM, this interaction can be stabilised by several ligands. Within a series of disubstituted amidoanthraquinones we find that the 2,7- regioisomer affords the best stabilisation of this TG triplex, though the 1,8- isomer also stabilises this interaction to some extent. By contrast the 1,5- and 2,6- regioisomers show no interaction with TG triplexes. Similar studies with a 13mer AG-containing oligonucleotide show the opposite pattern of stabilisation: the 2,6- and 1,5- isomers stabilise this triplex, but the 2,7- and 1,8-compounds do not. The polycyclic compound BePI strongly stabilises TG- but not AG-containing triplexes, while a substituted naphthylquinoline interacts with both antiparallel triplex motifs.

Stability of DNA triplexes on shuttle vector plasmids in the replication pool in mammalian cells

Triple helix-forming oligonucleotides may be useful as gene-targeting reagents in vivo, for applications such as gene knockout. One important property of these complexes is their often remarkable stability, as demonstrated in solution and in cells following transfection. Although encouraging, these measurements do not necessarily report triplex stability in cellular compartments that support DNA functions such as replication and mutagenesis. We have devised a shuttle vector plasmid assay that reports the stability of triplexes on DNA that undergoes replication and mutagenesis. The assay is based on plasmids with novel variant supF tRNA genes containing embedded sequences for triplex formation and psoralen cross-linking. Triple helix-forming oligonucleotides were linked to psoralen and used to form triplexes on the plasmids. At various times after introduction into cells, the psoralen was activated by exposure to long wave ultraviolet light (UVA). After time for replication and mutagenesis, progeny plasmids were recovered and the frequency of plasmids with mutations in the supF gene determined. Site-specific mutagenesis by psoralen cross-links was dependent on precise placement of the psoralen by the triple helix-forming oligonucleotide at the time of UVA treatment. The results indicated that both pyrimidine and purine motif triplexes were much less stable on replicated DNA than on DNA in vitro or in total transfected DNA. Incubation of cells with amidoanthraquinone-based triplex stabilizing compounds enhanced the stability of the pyrimidine triplex.

Linkage of a triple helix-forming oligonucleotide to amsacrine-4-carboxamide derivatives modulates the sequence-selectivity of topoisomerase II-mediated DNA cleavage

Amsacrine-4-carboxamide-oligonucleotide conjugates were synthesized and studied for their capacity to form DNA triple helices and to alter human topoisomerase II binding and cleavage properties. The intercalating agent was attached to the 3'- or the 5'-end of a 24 nt triple helix-forming oligonucleotide via linkers of different lengths. The stability of these DNA triple helices was investigated by gel retardation and melting temperature studies using a synthetic 70 bp DNA duplex target. The effect of the conjugates on DNA cleavage by topoisomerase II was evaluated using the 70 bp duplex and a 311 bp restriction fragment containing the same triple helix site. The conjugate with the amsacrine derivative linked to the 3' end of the TFO via a hexaethylene glycol linker modulates the extent of DNA cleavage by topoisomerase II at specific sites.

DNA triple helix stabilisation by covalent attachment of a triplex-specific ligand

We have prepared oligonucleotides with a naphthylquinoline triplex-binding ligand covalently tethered to the 5'-end and have used UV-melting and DNase I footprinting to examine the stability of intra- and inter-molecular triplexes containing this modification. We find that covalent attachment of the ligand increases the melting temperature of intramolecular 6-mer triplexes by about 14 K, and increases the binding of 9-mer oligonucleotides to their duplex target sites by about 60-fold.

DNA triple helix stabilisation by a naphthylquinoline dimer

We have used DNase I footprinting to examine the effect of a novel naphthylquinoline dimer, designed as a triplex-specific bis-intercalator, on the stability of intermolecular DNA triplexes. We find that this compound efficiently promotes triplex formation between the 9-mer oligonucleotide 5'-TTTTTTCTT and its oligopurine duplex target at concentrations as low as 0.1 microM, enhancing the triplex stability by at least 1000-fold. This compound, which is the first reported example of a triplex bis-intercalator, is about 30 times more potent than the simple monofunctional ligand.

Sequence-specific interactions of minor groove binders with restriction fragments of cDNAs for H tau 40 protein and MAP kinase 2. A qualitative and quantitative footprinting study

A series of DNA minor groove binders comprising netropsin, distamycin, the bisquaternary ammonium heterocycles SN 6999 and SN 6570, cis-diammine platinum(II)-bridged bis-netropsin, cis-diammine platinum(II)-bridged bis-distamycin and bis-glycine-linked bis-distamycin were investigated for sequence-specific interactions. The oligonucleotides used were the 154 base pair HindIII-RsaI restriction fragment of cDNA of h tau 40 protein and the 113 base pair NcoI-PvuII restriction fragment of cDNA of MAP kinase 2. Both proteins are believed to be involved in the pathology of Alzheimer's disease. For all these ligands, binding sites were localised at positions 1134-1139 (5'AATCTT3'), 1152-1156 (5'ATATT3') and 1178-1194 (5'TTTCAATCTTTTTATTT3') for the former and 720-726 (5'TATTCTT3'), 751-771 (5'AATTGTATAATAAATTTAAAA3') and 781-785 (5'TATTT3') for the latter. The AT-preference of ligand binding was obvious and footprint titration experiments were applied to estimate binding constants (Ka) for each individual binding site mentioned above. The binding strength decreases in the order netropsin > distamycin > SN 6999 approximately SN 6570>platinum-bridged netropsin or distamycin approximately bis-glycine-bridged distamycin and was found independently of the binding sites examined. GC-base pairs interspersed in short AT-tracts reduced the Ka-values by as much as two orders of magnitudes. The dependence of extended bidentate as well as of monodentate binding of netropsin and distamycin derivatives on the length of AT-stretches has been discussed.

Comb-type copolymer: stabilization of triplex DNA and possible application in antigene strategy

By employing a reductive amination reaction between the epsilon-amino groups of poly(L-lysine) (PLL) and the reductive ends of the hydrophilic dextran (Dex) side chain, we have prepared different comb-type copolymers which varied in the degree of grafting and the length of the hydrophilic Dex chains. The resulting copolymers, poly(L-lysine)-graft-dextran (PLL-g-Dex), were tested for their ability to stabilize triplex DNA in vitro under physiologically relevant conditions. Thermal denaturation (UV-Tm) and circular dichroism experiments revealed that the graft copolymer with the higher degree of grafting of long Dex chains significantly increased the thermal stability of triplex structure of poly(dA). 2poly(dT) by more than 50 degreesC without affecting the transition between triplex and single-stranded DNA or the native structure of DNA. Of importance is that when triplex formation involving a 30-mer target duplex from rat alpha1 (I) collagen promoter was analyzed by an in vitro electrophoretic mobility shift assay, the graft copolymer also remarkably diminished potassium inhibition of the purine motif triplex formation up to 200 mM as well as pH-dependence of the pyrimidine motif triplex formation. Moreover the triplex-stabilizing efficiency of the copolymer was significantly higher than that of other oligocations like spermine and spermidine. We suggest that a molecular design of comb-type copolymers consisting of various types of polycation backbones (e.g., PLL) grafted with different hydrophilic side chains (e.g., Dex) is a novel strategy to create efficient triplex stabilizers that will certainly shed light on possible in vivo application of the antigene strategy.

Poly(L-lysine)-graft-dextran copolymer: amazing effects on triplex stabilization under physiological pH and ionic conditions (in vitro)

Triplex DNA formation involving unmodified triplex-forming oligonucleotides (TFOs) is very unstable under physiological conditions. Here, we report a novel strategy to stabilize both purine and pyrimidine motif triplex DNA within the rat alpha1 (I) collagen gene promoter under physiologically relevant conditions by a poly(L-lysine)- graft -dextran copolymer. Using an in vitro electrophoretic mobility shift assay, we show that the copolymer almost completely abrogates the inhibitory effects of physiological concentrations of monovalent cations, particularly potassium ion (K+), on purine motif triplex formation involving very low concentrations of an unmodified guanine-rich TFO. Of importance, pH dependency in pyrimidine motif triplex formation involving an unmodified cytosine-rich TFO is also significantly overcome by the copolymer. Finally, the triplex-stabilizing efficiency of the copolymer is remarkably higher than that of other oligocations, like spermine and spermidine. We suggest that the ability of the graft copolymer to stabilize triplex DNA under physiologically relevant pH and salt concentrations will be a cue for further progress in the antigene strategy.

Interactions of the antiviral quinoxaline derivative 9-OH-B220 [2, 3-dimethyl-6-(dimethylaminoethyl)- 9-hydroxy-6H-indolo-[2, 3-b]quinoxaline] with duplex and triplex forms of synthetic DNA and RNA

The binding of an antiviral quinoxaline derivative, 2,3-dimethyl- 6 - (dimethylaminoethyl) - 9 - hydroxy - 6H - indolo - [2,3 - b]quinoxaline (9-OH-B220), to synthetic double and triple helical DNA (poly(dA).poly(dT) and poly(dA).2poly(dT)) and RNA (poly(rA). poly(rU) and poly (rA).2poly(rU)) has been characterized using flow linear dichroism (LD), circular dichroism (CD), fluorescence spectroscopy, and thermal denaturation. When either of the DNA structures or the RNA duplex serve as host polymers a strongly negative LD is displayed, consistent with intercalation of the chromophoric ring system between the base-pairs/triplets of the nucleic acid structures. Evidence for this geometry also includes weak induced CD signals and strong increments of the fluorescence emission intensities upon binding of the drug to each of these polymer structures. In agreement with intercalative binding, 9-OH-B220 is found to effectively enhance the thermal stability of both the double and triple helical states of DNA as well as the RNA duplex. In the case of poly(dA).2poly(dT), the drug provides an unusually large stabilization of its triple helical state; upon binding of 9-OH-B220 the triplex-to-duplex equilibrium is shifted towards higher temperature by 52.5 deg. C in a 10 mM sodium cacodylate buffer (pH 7.0) containing 100 mM NaCl and 1 mM EDTA. When triplex RNA serves as host structure, LD indicates that the average orientation angle between the drug chromophore plane and the helix axis of the triple helical RNA is only about 60 to 65 degrees. Moreover, the thermal stabilizing capability, as well as the fluorescence increment, CD inducing power and perturbations of the absorption envelope, of 9-OH-B220 in complex with the RNA triplex are all less pronounced than those observed for the complexes with DNA and duplex RNA. These features indicate binding of 9-OH-B220 in the wide and shallow minor groove of poly(rA).2poly(rU). Based on the present results, some implications for the applications of this low-toxic, antiviral and easily administered drug in an antigene strategy, as well as its potential use as an antiretroviral agent, are discussed.

Progress in developments of triplex-based strategies

Recognition of B-DNA by oligonucleotides that form triple helices is a unique method to specifically recognize sequences of double-stranded DNA. Recently, some significant limitations of the triple-based applications have been overcome. Stable intermolecular triplexes can be formed under physiologic conditions. Binding affinities of modified oligonucleotides to their target sequence due to Hoogsteen or reverse Hoogsteen hydrogen bonding interactions are now in the range of those obtained for duplex formation via Watson-Crick hydrogen bonding interactions even if the kinetics may be quite different. Progress has been made toward developing general procedures to determine the molecular mechanisms of action of triplex-forming oligonucleotides (TFO) administered to cultured cells to provide a rational proof-of-concept for antigene strategies. The antigene strategy has reached a point where TFOs can be used to interfere with several biologic progresses (replication, transcription, recombination, repair) in relevant systems both in vitro and ex vivo.