Linkage structures strongly influence the binding cooperativity of DNA intercalators conjugated to triplex forming oligonucleotides

Thermal stabilisation of the short DNA duplexes by acridine-4-carboxamide derivatives

The short oligodeoxynucleotide (ODN) probes are suitable for good discrimination of point mutations. However, the probes suffer from low melting temperatures. In this work, the strategy of using acridine-4-carboxamide intercalators to improve thermal stabilisation is investigated. The study of large series of acridines revealed that optimal stabilisation is achieved upon decoration of acridine by secondary carboxamide carrying sterically not demanding basic function bound through a two-carbon linker. Two highly active intercalators were attached to short probes (13 or 18 bases; designed as a part of HFE gene) by click chemistry into positions 7 and/or 13 and proved to increase the melting temperate (T_m) of the duplex by almost 8°C for the best combination. The acridines interact with both single- and double-stranded DNAs with substantially preferred interaction for the latter. The study of interaction suggested higher affinity of the acridines toward the GC- than AT-rich sequences. Good discrimination of two point mutations was shown in practical application with HFE gene (wild type, H63D C > G and S65C A > C mutations). Acridine itself can also serve as a fluorophore and also allows discrimination of the fully matched sequences from those with point mutations in probes labelled only with acridine.

Staggered intercalation of DNA duplexes with base-pair modulation by two distinct drug molecules induces asymmetric backbone twisting and structure polymorphism

The use of multiple drugs simultaneously targeting DNA is a promising strategy in cancer therapy for potentially overcoming single drug resistance. In support of this concept, we report that a combination of actinomycin D (ActD) and echinomycin (Echi), can interact in novel ways with native and mismatched DNA sequences, distinct from the structural effects produced by either drug alone. Changes in the former with GpC and CpG steps separated by a A:G or G:A mismatch or in a native DNA with canonical G:C and C:G base pairs, result in significant asymmetric backbone twists through staggered intercalation and base pair modulations. A wobble or Watson–Crick base pair at the two drug-binding interfaces can result in a single-stranded ‘chair-shaped’ DNA duplex with a straight helical axis. However, a novel sugar-edged hydrogen bonding geometry in the G:A mismatch leads to a ‘curved-shaped’ duplex. Two non-canonical G:C Hoogsteen base pairings produce a sharply kinked duplex in different forms and a four-way junction-like superstructure, respectively. Therefore, single base pair modulations on the two drug-binding interfaces could significantly affect global DNA structure. These structures thus provide a rationale for atypical DNA recognition via multiple DNA intercalators and a structural basis for the drugs’ potential synergetic use.

Spectroscopic study on the effect of imidazophenazine tethered to 5'-end of pentadecathymidilate on stability of poly(dA)·(dT)15 duplex

The effect of imidazo[4,5-d]phenazine (Pzn) attached to the 5(')-end of (dT)(15) oligonucleotide via a flexible linker on the thermal stability of poly(dA)·(dT)(15) duplex was studied in aqueous buffered solution containing 0.1 М NaCl at the equimolar ratio of adenine and thymine bases (100 μM each) using spectroscopic techniques. Duplex formation was investigated by measuring UV absorption and fluorescence melting curves for the Pzn-modified system. Tethered phenazine derivative enhances the thermostability of poly(dA)·(dT)(15) duplex increasing the helix-to-coil transition temperature by 4.5 °С due to an intercalation of the dye chromophore between AT-base pairs. The thermodynamic parameters of the transition for non-modified and modified systems were estimated using "all-or-none" model. The modification of the (dT)(15) results in a decrease in the transition enthalpy, however, the observed gain in the Gibbs free energy of complex formation, ΔG, is provided with the corresponding decrease in entropy change. The increase of ΔG value at 37 °C in consequence of (dT)(15) modification was found to be equal to 1.3 kcal/mol per oligonucleotide strand.

Synthesis of photo-responsive acridine-modified DNA and its application to site-selective RNA scission

Photo-responsive phosphoramidite monomers, which bear an azobenzene between acridine and the phosphoramidite unit, were synthesized, and incorporated into oligonucleotides. Upon UV irradiation, the azobenzene in the modified DNA efficiently isomerized from the trans isomer into the cis isomer. Although the T(m) values of their duplexes with complementary DNA were not much changed by the isomerization, site-selective RNA scission was significantly accelerated by the UV irradiation when Mn(II) ion was used as the catalyst for RNA scission.

DNA binding and antigene activity of a daunomycin-conjugated triplex-forming oligonucleotide targeting the P2 promoter of the human c-myc gene

Triplex-forming oligonucleotides (TFO) that bind DNA in a sequence-specific manner might be used as selective repressors of gene expression and gene-targeted therapeutics. However, many factors, including instability of triple helical complexes in cells, limit the efficacy of this approach. In the present study, we tested whether covalent linkage of a TFO to daunomycin, which is a potent DNA-intercalating agent and anticancer drug, could increase stability of the triple helix and activity of the oligonucleotide in cells. The 11mer daunomycin-conjugated GT (dauno-GT11) TFO targeted a sequence upstream of the P2 promoter, a site known to be critical for transcription of the c-myc gene. Band-shift assays showed that the dauno-GT11 formed triplex DNA with enhanced stability compared to the unmodified TFO. Band shift and footprinting experiments demonstrated that binding of dauno-GT11 was highly sequence-specific with exclusive binding to the 11 bp target site in the c-myc promoter. The daunomycin-conjugated TFO inhibited transcription in vitro and reduced c-myc promoter activity in prostate and breast cancer cells. The daunomycin-conjugated TFO was taken up by cells with a distinctive intracellular distribution compared to free daunomycin. However, cationic lipid-mediated delivery was required for enhanced cellular uptake, nuclear localization and biological activity of the TFO in cells. Dauno-GT11 reduced transcription of the endogenous c-myc gene in cells, but did not affect expression of non-target genes, such as ets-1 and ets-2, which contained very similar target sequences in their promoters. Daunomycin-conjugated control oligonucleotides unable to form triplex DNA with the target sequence did not have any effect in these assays, indicating that daunomycin was not directly responsible for the activity of daunomycin-conjugated TFO. Thus, attachment of daunomycin resulted in increased triplex stability and biological activity of the 11mer GT-rich TFO without compromising its specificity. These results encourage further testing of this approach to develop novel antigene therapeutics.

Anchorage of oligonucleotide hybridization by tethered phenazine nucleoside analogue

UV absorption and fluorescence techniques with a thermal denaturation procedure were used in studies of the anchorage of an oligonucleotide hybridization by a covalently tethered nucleoside analogue of an intercalating imidazophenazine derivative (Pzn). The formation by the (dT)(10)Pzn conjugate of the duplex complex with (dA)(15) and the triplex complex with (dA)(15) or poly(dA).poly(dT) was studied in buffered solutions with 0.11 and/or 1M sodium ions at the oligomer strand concentration of 10 microM. Because of the Pzn emission sensitivity to the interaction with adenine bases, a fluorescence technique was found to be effective in the detection of melting transitions. The attached Pzn substantially enhanced the thermal stability of complexes formed by (dT)(10) because of the intercalation mechanism, which increased the temperature of half-dissociation of the duplex by 10-12 degrees C and of the triplexes by approximately 13 degrees C. With the assumption of a two-state model of transition, the thermodynamic parameters for duplex formations were derived. The investigated variant of conjugation has a certain advantage over the widely used attachment via a flexible linker, consisting of a predetermined location of the Pzn chromophore in target sequences that makes it useful as a fluorescent reporter of the hybridization correctness. Molecular modeling was used to construct the geometries of the intercalation sites that turned out to be in conformity with the behavior of the Pzn fluorescence.

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 OsO(4)-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.

Triple helix formation and the antigene strategy for sequence-specific control of gene expression

Specific gene expression involves the binding of natural ligands to the DNA base pairs. Among the compounds rationally designed for artificial regulation of gene expression, oligonucleotides can bind with a high specificity of recognition to the major groove of double helical DNA by forming Hoogsteen type bonds with purine bases of the Watson-Crick base pairs, resulting in triple helix formation. Although the potential target sequences were originally restricted to polypurine-polypyrimidine sequences, considerable efforts were devoted to the extension of the repertoire by rational conception of appropriate derivatives. Efficient tools based on triple helices were developed for various biochemical applications such as the development of highly specific artificial nucleases. The antigene strategy remains one of the most fascinating fields of triplex application to selectively control gene expression. Targeting of genomic sequences is now proved to be a valuable concept on a still limited number of studies; local mutagenesis is in this respect an interesting application of triplex-forming oligonucleotides on cell cultures. Oligonucleotide penetration and compartmentalization in cells, stability to intracellular nucleases, accessibility of the target sequences in the chromatin context, the residence time on the specific target are all limiting steps that require further optimization. The existence and the role of three-stranded DNA in vivo, its interaction with intracellular proteins is worth investigating, especially relative to the regulation of gene transcription, recombination and repair processes.

Triple helix formation: binding avidity of acridine-conjugated AG motif third strands containing natural, modified and surrogate bases opposed to pyrimidine interruptions in a polypurine target

A critical issue for the general application of triple-helix-forming oligonucleotides (TFOs) as modulators of gene expression is the dramatically reduced binding of short TFOs to targets that contain one or two pyrimidines within an otherwise homopurine sequence. Such targets are often found in gene regulatory regions, which represent desirable sites for triple helix formation. Using intercalator-conjugated AG motif TFOs, we compared the efficacy and base selectivity of 13 different bases or base surrogates in opposition to pyrimidines and purines substituted into selected positions within a paradigm 15-base polypurine target sequence. We found that substitutions closer to the intercalator end of the TFO (positions 4-6) had a more deleterious effect on the dissociation constant (K d) than those farther away (position 11). Opposite T residues at position 11, 3-nitropyrrole or cytosine in the TFO provided adequate binding avidity for useful triplex formation (K ds of 55 and 110 nM, respectively). However, 3-nitropyrrole was more base selective than cytosine, binding to T >/=4 times better than to A, G or C. None of the TFOs tested showed avid binding when C residues were in position 11, although the 3-nitropyrrole-containing TFO bound with a K d of 200 nM, significantly better than the other designs. Molecular modeling showed that the 3-nitropyrrole.T:A triad is isomorphous with the A.A:T triad, and suggests novel parameters for evaluating new base triad designs.

Targeted gene knockout mediated by triple helix forming oligonucleotides

Triple helix forming oligonucleotides (TFOs) recognize and bind sequences in duplex DNA and have received considerable attention because of their potential for targeting specific genomic sites. TFOs can deliver DNA reactive reagents to specific sequences in purified chromosomal DNA (ref. 4) and nuclei. However, chromosome targeting in viable cells has not been demonstrated, and in vitro experiments indicate that chromatin structure is incompatible with triplex formation. We have prepared modified TFOs, linked to the DNA-crosslinking reagent psoralen, directed at a site in the Hprt gene. We show that stable Hprt-deficient clones can be recovered following introduction of the TFOs into viable cells and photoactivation of the psoralen. Analysis of 282 clones indicated that 85% contained mutations in the triplex target region. We observed mainly deletions and some insertions. These data indicate that appropriately constructed TFOs can find chromosomal targets, and suggest that the chromatin structure in the target region is more dynamic than predicted by the in vitro experiments.

1H NMR studies of the bis-intercalation of a homodimeric oxazole yellow dye in DNA oligonucleotides

We have used one and two dimensional 1H NMR spectroscopy to characterize the binding of a homodimeric oxazole yellow dye, 1,1'-(4,4,8,8-tetramethyl-4,8-diaza-undecamethylene)-bis-4-( 3-methyl-2,3-dihydro-(benzo-1,3-oxazole)-2-methylidene)-quinoliniu m tetraiodide (YOYO), to oligonucleotides containing the (5'-CTAG-3')2 and the (5'-CCGG-3')2 binding sites in either different oligonucleotides or in the same oligonucleotide. YOYO bis-intercalates strongly in all the oligonucleotides used and binds preferentially to a (5'-CTAG-3')2 binding site in the oligonucleotide d(CGCTAGCG)2 (1). YOYO also binds preferentially to a (5'-CCGG-3')2 sequence in the oligonucleotide d(CGCCGGCG)2 (2) but slightly less favorably than to the (5'- CTAG-3')2 sequence in 1. The binding of YOYO to the d(CGCTAGCCGGCG):d(CGCCGGCTAGCG) (3) oligonucleotide, containing two preferential binding sites, was also examined. YOYO forms mixtures of 1:1 and 1:2 complexes with oligonucleotide 3 in ratios dependent on the relative amount of YOYO and the oligonucleotides in the sample. The binding of YOYO to the oligonucleotide 3 occur sequence selective in the (5'-CTAG-3')2 site and the (5'- CCGG-3')2 site. We have also used two dimensional 1H NMR spectroscopy to determine the solution structure of the DNA oligonucleotide d(5'-CGCTAGCG-3')2 complexed with YOYO. The determination of the structure was based on a total relaxation matrix analysis of the NOESY cross peaks intensities. DQF-COSY spectra were used to obtain coupling constants for the deoxyribose ring protons. The coupling constants were transformed into angle estimates. The NOE derived distance and dihedral restraints were applied in restrained molecular dynamics calculations. Twenty final structures each were generated for the YOYO-complex from both A-form and B-form dsDNA starting structures giving a total of 40 final structures. Since many NOE contacts were observed between YOYO and dsDNA the resulting structure has a fairly high resolution and allows determination of local features in the dsDNA structure after YOYO binding. The root-mean-square (rms) deviation of the coordinates for the forty structures of the complex was 0.39 A. The local DNA structure is distorted in the complex. The helix is unwound by 106 degrees and has an overall helical repeat of 13 base pairs caused by the bis-intercalation of YOYO. The polypropylene amine linker chain is located in the minor groove of dsDNA. Even though the YOYO chromophore contains an oxygen atom instead of the larger sulphur atom in the corresponding compound, TOTO, the structures establish that YOYO require more space than TOTO in the intercalation sites. This is probably caused by the more rigid and planar chromophores in YOYO compared to TOTO.

Oligonucleotides as modulators of cancer gene expression

The delineation of gene function has always been an intensive subject of investigations. Recent advances in the synthesis and chemistry of oligonucleotides have now made these molecules important tools to study and identify gene function and regulation. Modulation of gene expression using oligonucleotides has been targeted at different levels of the cellular machinery. Triplex forming oligonucleotides, as well as peptide nucleic acids, have been used to inhibit gene expression at the level of transcription; after binding of these specific oligonucleotides, conformational change of the DNA's helical structure prevents any further DNA/protein interactions necessary for efficient transcription. Gene regulation can also be achieved by targeting the translation of mRNAs. Antisense oligonucleotides have been used to down-regulate mRNA expression by annealing to specific and determined region of an mRNA, thus inhibiting its translation by the cellular machinery. The exact mechanism of this type of inhibition is still under intense investigation and is thought to be related to the activation of RNase H, a ribonuclease that is widely available that can cleave the RNA/DNA duplex, thus making it inactive. Another well-characterized means of interfering with the translation of mRNAs is the use of ribozymes. Ribozymes are small catalytic RNAs that possess both site specificity and cleavage capability for an mRNA substrate, inhibiting any further protein formation. This review describes how these different oligonucleotides can be used to define gene function and discusses in detail their chemical structure, mechanism of action, advantages and disadvantages, and their applications.

Dynamic bis-intercalation of a homodimeric thiazole orange dye in DNA: evidence of intercalator creeping

We have used one and two dimensional exchange 1H NMR spectroscopy to characterize the dynamics of the binding of a homodimeric thiazole orange dye, 1,1'-(4,4,8,8-tetramethyl-4,8-diaza-undecamethylene)-bis- 4-(3-methyl-2,3-dihydro-(benzo-1,3-thiazole)-2-methylidene)-quinol inium tetraiodide (TOTO), to double stranded DNA (dsDNA). The double stranded oligonucleotides used were d-(CGCTAGCG)2 (1) and d(CGCTAGCTAGCG)2 (2). TOTO binds preferentially to the (5'-CTAG-3')2 sites and forms mixtures of 1:1 and 1:2 dsDNA-TOTO complexes with 2 in ratios dependent on the relative amount of TOTO and the oligonucleotide in the sample. The dynamic exchange between preferential binding sites in the case of a 2:1 1-TOTO mixture is an intermolecular exchange process between two binding sites on different oligonucleotides. In the case of the 1:1 2-TOTO complex an intramolecular exchange process occur between two different binding sites on the same strand. Both processes were studied. The results demonstrate the ability of TOTO to migrate along a dsDNA strand in an intramolecular exchange process. The migration process ("creeping") along the DNA strand is 6 times faster than the rate of intermolecular exchange between sites in two different oligonucleotides.

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.

Towards genomic drug therapy with antisense oligonucleotides

Antisense oligonucleotides represent a novel class of potential drugs for highly selective blocking of genes. The basic concept of antisense strategy is simple: an antisense molecule recognizes a complementary mRNA (or DNA) by sequence-specific base pairing, and hence prevents translation (or transcription), resulting in a selective inhibition of protein synthesis. Because of these properties, antisense oligonucleotides have great potential as therapeutic agents in several human diseases, such as viral diseases, malignancies and dominant hereditary diseases. However, technical difficulties have slowed down their use as drugs: structural modifications are needed to increase the stability and potency of synthetic oligonucleotides, specific delivery systems are required to facilitate their entry into target cells, and more information is needed to their mechanism of action. Much of the current research on antisense oligonucleotides takes place at the interface of chemistry and biomedical sciences, a multidisciplinary field where finding a common language is sometimes difficult. The aim of this review is to present an overview of the antisense strategy in terms which should be understandable for chemists, biologists and physicians.

Sequence-specific binding and cleavage of duplex DNA by a radioiodinated, intercalator-linked, triplex-forming oligonucleotide

Applications of oligodeoxynucleotides to modulate gene expression have been the subject of much recent research. We have sought to develop a method to permanently inactivate a gene, or potentially kill cells containing abnormal genes. In this report, we show that a DNA intercalator conjugated to a triplex-forming oligonucleotide can be labeled with an Auger electron emitting radioisotope, can cleave its duplex DNA target, and can specifically bind the target sequence contained in a total of 10 kilobases of irrelevant DNA.

Bis-intercalation of a homodimeric thiazole orange dye in DNA in symmetrical pyrimidine-pyrimidine-purine-purine oligonucleotides

One- and two-dimensional 1H NMR spectroscopy were used to characterize the binding of a homodimeric thiazole orange dye, 1,1'-(4,4,8,8-tetramethyl-4,8-diazaundecamethylene)-bis-4-(3 -methyl-2,3-dihydro-(benzo- 1,3-thiazole)-2-methylidene)-quinolinium tetraiodide (TOTO), to various double-stranded DNA oligonucleotides containing symmetric (5'-pyr-pyr-pu-pu-3')2 or (5'-pu-pu-pyr-pyr-3')2 sequences. It was found that TOTO binds preferentially to oligonucleotides containing a (5'-CTAG-3')2 or a (5'-CCGG-3')2 sequence. Binding to the (5'-CCGG-3')2 sequence is less favored than to the (5'-CTAG-3')2 sequence. The complexes of TOTO with d(CGCTAGCGCTAGCG)2 (10) and d(CGCTAGCCGGCG):d(CGCCGGCTAGCG) (11) oligonucleotides, each containing two preferential binding sites, was also examined. In both cases TOTO forms mixtures of 1:1 and 1:2 dsDNA-TOTO complexes in ratios dependent on the relative amount of TOTO and the oligonucleotides in the sample. Binding of TOTO to the two oligonucleotides is sequence selective at the (5'-CTAG-3')2 and (5'-CCGG-3')2 sites. The 1H NMR spectra of both the 1:2 complexes and the three different 1:1 complexes have been assigned. A slight negative cooperativity is observed in formation of the 1:2 complexes. The ratio between the two different 1:1 complexes formed with oligonucleotide 11 is 2.4 in favor of binding to the (5'-CTAG-3')2 site. This is very similar to results obtained when the two sites are in different oligonucleotides. Thus the distribution of TOTO among the (5'-CTAG-3')2 and (5'-CCGG-3')2 sites is independent of whether the two sites are in the same or two different oligonucleotides.

Antigene, ribozyme and aptamer nucleic acid drugs: progress and prospects

Nucleic acids are increasingly being considered for therapeutic uses, either to interfere with the function of specific nucleic acids or to bind specific proteins. Three types of nucleic acid drugs are discussed in this review: aptamers, compounds which bind specific proteins; triplex forming (antigene) compounds; which bind double stranded DNA; and ribozymes (catalytic RNA), which bind and cleave RNA targets. The binding of aptamers to protein may involve specific sequence recognition, although this is not always the case. The interaction of triplex forming oligonucleotides or ribozymes with their targets always involves specific sequence recognition and hybridization. Early optimism concerning the possibility of designing drugs without a priori knowledge of the structure of the target (except a nucleotide sequence) has been tempered by the finding that target structure has a dramatic effect upon the hybridization potential of the nucleic acid drug. Other obstacles to the creation of effective nucleic acid drugs are their relative high molecular weight (> 3300) and their sensitivity to degradation. The molecular weight of these compounds has created a significant delivery problem which needs to be solved if nucleic acid drugs are to become effective therapies.